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Burning Speeds, Flame Kernel Formation and Flame Structure of Bio-jet and JP8 Fuels at High Temperatures and Pressures
by
Kian Eisazadeh-Far
to
The Department of Mechanical and Industrial Engineering
In partial fulfillment of the requirements for the degree of
Doctor of Philosophy
in the field of
Mechanical Engineering
Northeastern University
Boston, Massachusetts
August 2010
2
PhD committee members
Professor Hameed Metghalchi (principal advisor): Professor and Chair,
Mechanical and Industrial Engineering Department, Northeastern University,
Boston, MA
Professor Yiannis Levendis: Professor, Mechanical and Industrial Engineering
Department, Northeastern University, Boston, MA
Dr. Victor Wong: Principal Research Engineer, Department of Mechanical
Engineering, Massachusetts Institute of Technology, Cambridge, MA
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Those who went in pursuit of knowledge
Soared up so high, stretched the edge
Were still encaged by the same dark hedge
Brought us some tales ere life to silence pledge.
Omar Khayyam (1048—1131 AD)
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To my parents:
Shamsi and Hassan Eisazadeh-Far
Who always have inspired me with their love
AND
To the memory of Professor James C Keck (1924-2010)
Who taught me the art of simple assumptions achieved from deep understanding
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Table of Contents
Acknowledgements ...........................................................................................................................9
Abstract ..........................................................................................................................................11
1. Introduction................................................................................................................................12
1.1. Introduction ........................................................................................................................ 13
1.1.1. Importance of Flame Formation, Laminar Burning Speed, Flame Structure ...................... 13
1.1.2. Fuels ..................................................................................................................................... 14
1.2. Burning Speed Measurement ............................................................................................. 16
1.2.1. Experimental Facilities ........................................................................................................ 17
1.3. Structure of Thesis ............................................................................................................. 20
2. Planar Laser Induced Fluorescence (PLIF) System ..................................................................23
2.1. Planar Laser Induced Fluorescence (PLIF) System ........................................................... 24
2.1.1. Pump Laser .......................................................................................................................... 24
2.1.2. Dye Laser ............................................................................................................................. 26
2.1.3. Camera ................................................................................................................................. 29
2.1.4. Combustion Facilities of PLIF System ................................................................................ 29
2.1.5. Calibration and Synchronization of the System ................................................................... 31
3. Thermodynamic Properties of Ionized Gases at High Temperatures ........................................33
Abstract ..................................................................................................................................... 34
3.1. Introduction ........................................................................................................................ 35
3.2. General Model ................................................................................................................... 36
3.2.1. Dissociation ......................................................................................................................... 36
3.2.2. Ionization Process ................................................................................................................ 38
3.3. Results and Discussion ...................................................................................................... 40
3.4. Comparison with Other Calculations ................................................................................. 42
4. A Thermodynamic Model for Argon Plasma Kernel Formation ...............................................57
Abstract ..................................................................................................................................... 58
4.1. Introduction ........................................................................................................................ 58
4.2. Experimental System ......................................................................................................... 59
4.3. Experimental Results ......................................................................................................... 60
4.3.1. Discharge Energy ................................................................................................................. 60
4.3.2. Image Capturing .................................................................................................................. 61
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4.4. Thermodynamic Model ...................................................................................................... 61
4.4.1. Thermodynamic Properties .................................................................................................. 63
4.5. Results and Discussion ...................................................................................................... 63
4.5.1. Initial Radius ........................................................................................................................ 63
4.5.2. Initial Temperature .............................................................................................................. 63
4.5.3. Result of Calculations .......................................................................................................... 64
5. On Flame Kernel Formation and Propagation in Premixed Gases ..........................................76
Abstract ..................................................................................................................................... 78
5.1. Introduction ........................................................................................................................ 78
5.2. Experimental System ......................................................................................................... 79
5.3. Experimental Results ......................................................................................................... 80
5.3.1. Discharge Energy Measurements ........................................................................................ 80
5.3.2. Shadowgraphs of the Kernel ................................................................................................ 81
5.3.3. Kernel Growth for Air ......................................................................................................... 81
5.4. Thermodynamic Model ...................................................................................................... 81
5.4.1. Thermodynamic Properties .................................................................................................. 83
5.4.2. Electrical Energy ................................................................................................................. 83
5.4.3. Conduction to Electrodes by Thermal Boundary Layer ...................................................... 84
5.4.4. Effect of Initial Temperature ............................................................................................... 84
5.4.5. Effect of Initial Radius ......................................................................................................... 84
5.4.6. Best Fit to the Model ........................................................................................................... 84
5.4.8. Fraction of Total Energy Losses .......................................................................................... 85
5.5. Methane/Air Mixture ........................................................................................................ 85
5.5.1. Flame radius ......................................................................................................................... 85
5.5.2. Model Equations .................................................................................................................. 86
5.6. Errors and Uncertainties .................................................................................................... 88
5.7. Comparison with Other Experimental Data ....................................................................... 88
6. A Thermodynamic Model to Calculate Burning Speed of Methane-Air- Diluent Mixtures ....112
Abstract ................................................................................................................................... 114
6.1. Introduction ...................................................................................................................... 116
6.2. Experimental Facilities .................................................................................................... 117
6.3. Theoretical Model ............................................................................................................ 119
6.3.1. Burned Gas Mass Fraction and Temperature ..................................................................... 119
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6.3.2. Burning Speed, Flame Speed and Gas Speed .................................................................... 125
6.4. Comparison of Experimental Data with Model Predictions ............................................ 126
7. Flame Structure and Laminar Burning Speeds of JP-8/air Premixed Mixtures at High
Temperatures and Pressures ........................................................................................................142
Abstract ................................................................................................................................... 144
7.1. Introduction ...................................................................................................................... 144
7.2. Experimental Facility ....................................................................................................... 145
7.3. Flame Structure ................................................................................................................ 148
7.4. Burning Model ................................................................................................................. 149
7.4.1. Governing Equations ......................................................................................................... 149
7.5. Laminar Burning Speeds .................................................................................................. 152
8. The Effect of Diluent on Flame Structure and Laminar Burning Speeds of JP-
8/oxidizer/diluent Premixed Flames ............................................................................................170
Abstract ................................................................................................................................... 171
8.1. Introduction ...................................................................................................................... 171
8.2. Experimental Facility ....................................................................................................... 172
8.2.1. Vapor pressures and Temperatures .................................................................................... 173
8.2.2. Fuel Cracking at High Temperatures ................................................................................. 173
8.3. Experimental Results and Discussion .............................................................................. 174
8.3.1. Experiments with Air and EDG ......................................................................................... 174
8.3.2. Experiments with Helium and Argon ................................................................................ 176
8.4. Burning Speed Measurements ......................................................................................... 177
8.4.1. Burning Model .............................................................................................................. 177
8.4.2. Laminar Burning Speeds ................................................................................................... 179
9. Laminar Burning Speeds of Ethanol/Air/Diluent Mixtures .....................................................202
Abstract ................................................................................................................................... 204
9. 1. Introduction ..................................................................................................................... 206
9.2. Experimental Facilities .................................................................................................... 207
9.3. Burning Model ................................................................................................................. 207
9.4. Results .............................................................................................................................. 208
9.5. Comparison with Other Measurements ........................................................................... 211
10. Laminar burning speeds of advanced bio-jet fuels ................................................................222
10.1. Bio-based Alternative Fuels for JP-8 ............................................................................. 223
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10.2. Laminar Burning Speeds......................................................................................... 225
11. Summary and Conclusions .....................................................................................................227
11.1. Thermodynamic Properties of Ionized Gases at High Temperatures ............................ 228
11.2. A Thermodynamic Model for Argon Plasma Kernel Formation ................................... 228
11.4. A Thermodynamic Model to Calculate Burning Speed of Methane-Air- Diluent Mixtures
................................................................................................................................................. 230
11.5. Flame Structure and Laminar Burning Speeds of JP-8/air Premixed Mixtures at High
Temperatures and Pressures .................................................................................................... 231
11.6. The Effect of Diluent on Flame Structure and Laminar Burning Speeds of JP-
8/oxidizer/diluent Premixed Flames ....................................................................................... 232
11.7. Laminar Burning Speeds of Ethanol/Air/Diluent Mixtures ........................................... 232
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Acknowledgements
The joy of exploring science has been a great source of personal happiness to me these past five
years. Living and working in one of the intellectual and scientific capitals of the world-- Boston,
Massachusetts-- has inspired me to greater ambitions than I ever entertained as a young boy in
Iran. I began my PhD when I was 25 years old and now on the eve of turning 30, I feel excited,
knowing that I have so much more to do and so many new questions to explore.
At the conclusion of this wonderful chapter in my life, I am indebted to many people. My first
and most important thanks go to Professor James C. Keck of MIT, whose scientific mind was an
invaluable source of feedback and inspiration to me. Through him, I have learned the enormous
value of scientific fundamentals and of details in research—even if those details do not always
seem important at the time. Professor Keck was a great teacher to me, and not just in science. He
taught me to cultivate discipline and order in my life and shown me how beautiful the world can
be when one pursues both intellectual and family life with determination and passion. I would
like to express my deepest gratitude to Professor Keck for many great conversations and lessons
over the past 5 years. After he passed away four days after my defense, I feel a great void and I
hope he is resting in peace!
I would also like to thank my great advisor, Professor Hameed Metghalchi, for his support and
good humor. Prof. Metghalchi has always been a dependable source of good advice, scientific
feedback, and moral support. I feel exceptionally lucky to have known and worked with him. I
am delighted to express many thanks to Professor Metghalchi for his encouragement and
friendship. I hope to make him proud in my future endeavors.
Many thanks go to my PhD committee members-- Professor Yiannis Levendis and Professor
Victor Wong for the valuable discussions that we had about my thesis. I was honored to have
their brilliant comments about my research. I am grateful to all the Northeastern University
professors from whom I learned so much. Professor John Cipolla, Professor Hamid N. Hashemi,
Professor M. Taslim, and all my other teachers-- thank you very much!
The company of wonderful colleagues in our combustion lab of Northeastern has been a very
important element of my growth and happiness at this university. Specially, Mr. Mohammad
Janbozorgi, my dear friend and brilliant colleague, whose dedication to science inspires and
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motivates me daily. I wish him a success in his career and much personal success and happiness.
I am thankful for Dr. Farzan Parsinejad, my one-time colleague and dear friend for his support
and assistance. Warm thanks go to my esteemed colleagues: Mr. Edwin Shirk, Mr. Raymond
James Andrews, Mr. Matt Gautreau, Mr. Mimmo Elia, Mr. Ali Moghaddass, Dr. Donald
Goldwaite, Mr. Ghassan Nicolas, Mr. Yue Gao, Mr. Jason Targof, Mrs. Adrienne M. Jalbert, and
especially Mr. Colin Fredette, for countless hours of hard work on the PLIF system developed in
our lab.
I would like to express my gratitude to the staff of the mechanical engineering department for
their kindness and helpfulness. I would especially like to thank Mr. Kevin Mccue, who helped
me a lot in technical problems in our lab. I also had very interesting discussions with Kevin
about history and politics. I wish him luck and happiness.
I have made wonderful friends in Boston without whose support this moment might have been
impossible (or at least severely delayed!). I am particularly grateful to the fellow members of the
Thursday night Iranian History Club, who have enriched my life with their diverse perspectives
on so many topics. I will always be grateful to my dearest and closest friend, Sylvana Habdank-
Kolaczkowska, for her great love and support during my PhD. I am so lucky to have her in my
life!
Finally, I am incredibly indebted to my family for their unfailing love and support throughout my
life. To my father, Mr. Hassan Eisazadeh-Far, who is my moral compass and my inspiration in so
many ways, and to my mother, Mrs. Shamsi Eisazadeh-Far, whose great love and compassion
both humbles and inspires me. The sacrifices they have made to bring me here are enormous, and
there are no words to describe my love and gratitude.
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Abstract
Fundamental concepts of laminar flames have been studied both experimentally and
theoretically. Topics such as, thermodynamic properties of gases at high temperatures, plasma
formation in argon and air, flame kernel development, flame structure, burning speed of jet fuels
such as ethanol, JP-8 and biomass based fuel have been studied.
The formation and propagation process of flame were studied in detail by a new model. Three
important parameters affecting the formation and propagation of flame are: electrical discharged
energy, chemical energy and energy transfer to the gas and electrodes. The roles of these
parameters were studied and fundamental properties of laminar flames like laminar burning
speed were measured at constant temperatures and pressures. As a part of this study the
thermodynamic properties of inert gases including oxygen, nitrogen, air, argon and helium were
measured at extremely high temperatures. These properties were necessary for the model
developed for plasma and flame kernel growth.
Laminar burning speeds of jet fuels (JP-8) and their biomass based alternatives which were R-8
(POSF 5469) and ethanol are measured at high temperatures (500-650 K) and pressures (1-7
atm). The experiments were carried out in two constant volume spherical and cylindrical
vessels. The laminar burning speeds of these fuels were compared with each other and also with
results of other researchers.
Flame structure of premixed spherical flames was studied in shadowgraph optical system and an
advanced Planar Laser Induced Fluorescence (PLIF) system. Flame structure study includes cell
instability analyses, cell formation, and profile of OH molecule within the flame. The effect of
different diluents like argon and helium were investigated at several temperatures and pressures.
One of the main goals was to achieve laminar flames at higher pressures. The important
parameters which were investigated were pressure, temperature, equivalence ratio, flame
thickness, diluent type and stretch factor.
Introduction of a new experimental set up which is an advanced Planar Laser Induced
Fluorescence (PLIF) system: Installation, design, and operation of this system are one of
important objectives of this thesis. This system is used for combustion diagnostics and flame
behavior study. The details of PLIF system will be descried in chapter 1 (introduction).
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1. Introduction
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1. Introduction
1.1. Introduction
1.1.1. Importance of Flame Formation, Laminar Burning Speed, Flame Structure
Among the important thermo-physical properties of every fuel, is its laminar burning speed.
Burning speed is used in turbulent combustion modeling as well as validating chemical kinetic
models. There are various methods to measure laminar burning speed [1-16]. The important
point is to use a method by which laminar burning speed can be measured in a wide range of
pressures and temperatures with a high accuracy. In this thesis laminar burning speeds are
measured by two different techniques: 1- a new model (constant pressure model) which
measures burning speeds at constant pressure and temperature, and 2-pressure rise method by
performing experiments in constant volume vessel to measure the burning speed at high
temperatures and pressures.
Constant pressure model investigates the formation and propagation of premixed flames. Flame
kernel formation and development are important phenomena in premixed flames. It involves the
evolution of flame from plasma to a self-sustained region when diffusion and transport
phenomena take over the propagation of flame. In this thesis some fundamental properties of
flame including laminar burning speeds are measured using a new model which includes the
properties of the hot gas in plasma region. The results of this model demonstrate the role of three
different major terms which are: electrical energy added to mixture by spark electrodes, energy
released due to chemical reactions in flame front and energy transfer from burned gas to the
spark electrodes. The new model works just in constant pressure conditions.
The second approach is use of pressure rise in the vessel: in this method the burning speeds are
measured in variant temperatures and pressures by conducting experiments in a constant volume
combustion chamber. Higher temperatures and pressures will be obtained by changing the
diluent from nitrogen to helium. Another feature of this research is addition of Extra Diluent
gases (ED) which is (N2+CO2) to the mixture to investigate their effect on laminar burning speed
and flame structure. ED gases can simulate exhaust gas recirculated diluent (EGR) gases which
exist in internal combustion engines. ED gases increase the heat capacity of the mixture,
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decrease the adiabatic flame temperature and decrease the laminar burning speed. A
shadowgraph optical system has been used to observe the shape of the flames and ensure that
they were laminar. The effect of mentioned parameters (temperature, pressure, equivalence ratio,
ED gases, and other diluents) on instability and turbulence initiation in spherical flames has been
investigated by conducting and analyzing the relevant experiments.
1.1.2. Fuels
Different fuels have been used in this research for measurement of laminar burning speeds and
flame structure study. These fuels include fossil-based Jet Propellant (JP-8) and its bio-based
alternative fuels. These are ethanol and R-8 fuel.
1.1.2.1. JP-8
Currently, JP-8 which is a fossil-based fuel is widely used in aircrafts and diesel engines. This
fuel not only is applied as the main source of energy in combustors but also as coolant and
lubricant. JP-8 and Jet A-1 have similar chemical structures because JP-8 is formed from Jet A-1
using some special additives to improve thermal stability characteristics [17]. JP-8 can be used as
an alternative for diesel fuel because of their similar thermal and chemical properties. Due to its
acceptable thermal stability parameters, its low freezing point of <-60 ˚C, and its dual application
as both a coolant and an energy source, JP-8 is widely applied to aircraft engines and gas-
turbines [18].
JP-8 is a complex chemical component composed of aromatics, n-paraffins, and cycloparaffins
[19-20]. It also includes other chemical components which are difficult to detect. However, the
main constituent of this fuel are paraffins and aromatics. The concentrations of chemical
components are different for several versions of JP-8 produced in refineries. But gas
chromatography studies prove that the main components which are paraffins and aromatics have
identical concentrations. Figure 1 shows the gas chromatograph of JP-8 (4658+additives) fuel.
This figure demonstrates that n-paraffins in the range of C9-C15 have the highest concentrations
in the fuel.
15
Figure 1: Chromatograph of JP-8 (4658+additives)
1.1.2.2. Biofuels
Bio-jet fuels are important alternative energy resources for aviation purposes. These fuels
can be obtained from several resources like corn, sugar, algae, biomass, etc. due to water and
food resources limitation in the world it is preferred to use non-edible resources to produce bio-
jet fuels. One of the reliable resources for obtaining bio-jet fuels is biomass. Biomass is abundant
in nature and it does not waste edible resources. Biomass is a renewable resource of energy. The
produced CO2 from the combustion of biomass fuels can be a part of biomass creation cycle loop
in the nature. Therefore the net emitted CO2 of bio-fuel production and combustion is low and it
makes it a renewable and fairly clean fuel.
There are various classes of aviation biofuels. The most common ones are alcohol fuels.
They can be produced both from edible resources like corn and non-edible resources like
biomass. Among alcoholic fuels ethanol is the most popular one; it is widely used in land based
engines but not so popular in aviation engines. The ideal fuel for aviation fuel is the one which
can be used both as energy source and coolant. Currently, JP-8 fossil fuel is widely used in
aviation and satisfies the mentioned requirements. The attempt is focused on finding the best bio-
jet fuel which is similar to JP-8. The class that is most advanced is "hydrotreated renewable jet"
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(HRJ), which is hydrotreated fats/oils. This fuel is very similar to Fischer-Tropsch synthetic
paraffinic kerosene. The fuel called R-8 (POSF 5469) is a fuel produced by hydrotreating
fats/oils (triglycerides) and contains n-paraffins and iso-paraffins. HRJ fuels are predominantly
n-paraffins and iso-paraffins. The other fuel is produced from biomass by a different process,
and contains aromatics. The applied bio-jet fuels in this research will be ethanol and R-8 (POSF
5469). Table 1 presents the properties of conventional fossil-based and bio-based fuels which are
JP-10, JP-8, ethanol and R-8.
Table 1: properties of fossil-based and bio-based fuels
JP-10 JP-8 Ethanol R-8
Chemical formula C10H16 C12H23 C2H5OH C10.9H23.9
Heat of combustion: (MJ/kg) 42.01 42.8 29.7 44.1
Flash point (K) 327.4 311 285.15 321
Volatility
Density (kg/L) 0.94 0.81 0.79 0.75
Distillation
Initial boiling point (K) 460.2 ± 0.2 320 351.5 ± 0.2 342
10% recovered (K) 460.2 ± 0.2 426 351.5 ± 0.2 398
20% recovered (K) 460.2 ± 0.2 435 351.5 ± 0.2 424
50% recovered (K) 460.2 ± 0.2 450 351.5 ± 0.2 469
90% recovered (K) 460.2 ± 0.2 481 351.5 ± 0.2 509
Final boiling point (K) 460.2 ± 0.2 498 351.5 ± 0.2 560
Fluidity
Viscosity (mm2/s @253 K) 1.3 2.12 2.9 5.5
Freezing point (°C) -79 -47 -114 -49
Figure 2 shows the chromatograph of R-8 fuel. It can be seen that this fuel is composed of
several elements and the major ones are n-paraffins.
1.2. Burning Speed Measurement
Among the important thermo-physical properties of each fuel, are its burning speed and flame
structure. Burning speed is used in turbulent modeling of internal combustion engines as well as
validating chemical kinetic models. These combustion characteristics need to be measured both
for different JP-8 fuels and its surrogates in a wide range of pressure and temperature. This
information will be also used in validating chemical kinetics models. These combustion
17
characteristics will be measured in the Combustion Laboratory of Northeastern University.
Figure 2: Chromatogram of R-8 fuel
1.2.1. Experimental Facilities
1.2.1.1. Spherical Vessel
Burning speed measurements will be made in the existing spherical and cylindrical combustion
chambers. The spherical chamber consists of two hemispheric heads bolted together to make a
15.24 cm inner diameter sphere. The chamber was designed to withstand pressures up to 425 atm
and is fitted with ports for spark electrodes, diagnostic probes, and ports for filling and
evacuating it. A thermocouple inserted in one of the chamber ports will be used to check the
initial temperature of the gas inside the chamber. A Kistler 603B1 piezo-electric pressure
transducer with a Kistler 5010B charge amplifier will be used to obtain dynamic pressure vs.
time records from which the burning speed will be determined. Ionization probes mounted flush
with the wall located at the top and bottom of the chambers will be used to measure the arrival
time of the flame at the wall and to check for spherical symmetry and buoyant rise.
The spherical chamber is housed in an oven which can be heated up to 500 K. Liquid fuel
is stored in a 115 cc heated pressure chamber and is transferred through a heated line (500 K) to
C15H32
C16H34
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C8H18
C7H16
R-8 bio-jet
C15H32
C16H34
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C8H18
C7H16
C15H32
C16H34
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C8H18C15H32
C16H34
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C15H32
C16H34
C15H32
C16H34
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C8H18
C7H16
R-8 bio-jet
18
the spherical chamber in the oven. Several thermocouples are located on the line from the fuel
reservoir to the chamber to monitor temperature of the fuel passageway. A heated strain gauge
(Kulite XTE-190) in the oven is used to measure partial pressure of fuel in the chamber.
Figure 3: the sketch of the spherical vessel
1.2.1.2. Cylindrical Vessel
The companion cylindrical chamber is made of SAE4140 steel with an inner diameter and
length of 133.35 mm. The two end windows are 34.93 mm thick Fused-silica with a high
durability against pressure and temperature shocks as well as having very good optical
properties. This chamber was designed to operate over the same pressure and temperature range
as the spherical chamber and is equipped with similar access ports. This chamber is used to
measure pressure rise due to combustion process and to permit optical observation of the flame
19
shape and structure under conditions as close as possible to those in the spherical chamber and to
insure the initial development of the flame and pressure rise are identical in both chambers. Two
band heaters and a rope heater wrapped around the cylindrical chamber are used to heat up the
chamber to 500 K. This chamber is equipped with a heated liquid fuel line system, a pressure
strain gauge and thermocouples similar to the spherical chamber. A Z-type
Schlieren/Shadowgraph ensemble has been set up to visualize the flame propagation. The light
source for the optical system is a 10-Watt Halogen lamp with a condensing lens and a small
pinhole of 0.3 mm in diameter, which provides a sharp and intense illumination throughout the
whole system. Two aluminized spherical mirrors with 1/8 wavelength surface accuracy, over-
coated with silicon monoxide and mounted in metal-stands with a diameter of 152.4 mm and
focal length of 1524 mm, are placed on two sides of the chamber. A high speed CMOS camera
(1108-0014, Redlake Inc.) with a capture rate of up to 40,000 frames per second is placed very
close to the focal point of the second mirror. The capture rate and shutter speed of the camera are
optimized depending on the burning speed of the mixture and the brightness of the flame. Figure
4 shows the configuration of the shadowgraph system.
20
Figure 4: the configuration of the optical and shadowgraph system
1.3. Structure of Thesis
The structure of this thesis is based on the manuscripts published and submitted to journals
during PhD years. Each chapter is represented by a paper. Chapter 2 discusses about a recently
designed and developed Planar Laser Induced Fluorescence (PLIF) system. Chapters 3-5
discuss about the thermodynamic properties of inert gases at temperature range of 300-100,000
K, plasma kernel formation of argon and air, and formation and propagation of premixed
flames. Chapter 6 describes details of the thermodynamic model which measures the laminar
burning speeds of spherical flames by pressure rise method. Chapter 7 and 8 present the laminar
21
burning speeds of JP-8/oxidizer/diluent mixtures at high temperatures and pressures along with
a detailed study on flame structure of JP-8/oxidizer/diluent flames at various temperatures,
pressures, equivalence ratios, and diluent types. Chapter 9 is laminar burning speeds of bio-
fuels. Chapter 9 studies ethanol/air/diluent mixtures. Chapter 10 investigates the molecular
structure of R-8 fuel along with laminar burning speed data.
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[17]. Rawson P. AMRL evaluation of the JP-8+100 jet fuel thermal stability additive, Technical
Report (DSTO Aeronautical and Maritime Research Laboratory), Airframes and Engines
Division, DSTO-TR-1135.
[18]. Fernandes G, Fuschetto J, Filipi Z, Assanis D, McKee H. Journal of Automobile
Engineering, Proceedings of the Institution of Mechanical Engineers Part D, London,
(2007) ;221(8):957–70.
[19]. Dagaut P, Cathonnet M. Progress in Energy and Combustion Science (2006); 32:48-92
(Issue 1).
[20] Agosta A, Cernansky NP, Miller DL, Faravelli T and Ranzi E. , Experimental Thermal and
Fluid Science (2004) ;28:701-708 (Issue 7).
23
2. Planar Laser Induced Fluorescence (PLIF)
System
24
2. Planar Laser Induced Fluorescence (PLIF) System
2.1. Planar Laser Induced Fluorescence (PLIF) System
PLIF device is an advanced system for combustion diagnostics. It is composed of a Nd-Yag
laser, a Dye laser, a power supply, a CCD camera and optical devices like mirrors, lenses and
scopes. A cylindrical chamber has been designed and installed in PLIF system. Its geometry and
structure is like the shadowgraph system chamber, but it has two more optical windows at its
sides to allow the laser beam to come inside and excite the molecules. The ignition and data
acquisition system are synchronized by the DaVis software (laser professional software). There
are different filters and Dye materials which enable the system to operate at different
wavelengths to measure the concentrations of other molecules like CH and NO. The camera is a
Lavision advanced camera coupled with the computer to analyze the fluoresced data from the
chamber. A flat flame burner is installed with this system to calibrate the OH concentration
measurement. After calibration process, the OH concentrations will be measured at high
temperatures and pressures. In following sections the devices are described in more detail.
2.1.1. Pump Laser A Spectra-Physics Quanta-Ray Lab-190 Laser is used to produce the initial pump laser beam. A
generalized diagram is shown in Figure 1.
25
Figure 1: Spectra-Physics Nd:YAG (pump) laser schematic, adapted from [1].
The Lab-190 uses a flash lamp to optically stimulate neodymium-doped yttrium aluminum
garnet (Nd:YAG) in the crystal’s red and near infrared absorption bands. This absorption causes
a population inversion, depicted in Figure . Atoms in the crystal are excited from energy level E1
to E4 by the flash lamp; however the atoms are unstable in this elevated level.
Figure 2 – Depiction of population inversion, adapted from [2].
Since there is a greater transition probability to E3 than back to E1 the atoms quickly decay to E3.
This third level is metastable, so the atoms remain at this level for a relatively long amount of
26
time, roughly 230 μs. From E3, there are several other energy levels (not pictured) that the atoms
could decay to, the most probable being E2. The transition from E3 to E2 is called the lasing
transition because this is where the fundamental wavelength of 1064 nm is generated. The E2
state is also unstable, so once atoms decay from E3, they quickly transition down from E2 back to
E1. This behavior causes the population of atoms in the third energy level to grow larger than
that of the second level, hence the population inversion. This inversion is what allows light
passing through the crystal to be amplified, with a larger inversion producing a larger
amplification [2].
The pump laser also uses a Q-switch to produce short bursts of high intensity beams. Without it,
the length of the laser pulse would be similar to the length of the flash lamp and have a low
maximum power. The Q-switch allows the Nd:YAG crystal to reach the maximum population
inversion at which point the switch quickly opens causing a quick release of energy, forming a
beam that is less than 10 ns long and a peak optical power of tens of megawatts. This high
powered beam is then sent through several non-linear conversion processes. Two such
processes, frequency doubling and frequency mixing, occur in the Nd:YAG’s Harmonic
Generator (HG) which houses potassium dideuterium phosphate (KD*P) crystals. Depending on
the configuration of these crystals, the HG can be used to either polarize the fundamental
wavelength (1064 nm) or generate the second harmonic (532 nm), third harmonic (355 nm) or
fourth harmonic (266 nm). The second and third harmonics are often used with dye laser
systems because they have high dye conversion efficiency. Finally, just before the beam exits
the Nd:YAG, it is reflected by two Dichroic mirrors which are designed to reflect only specific
wavelengths of light and allow everything else to pass through it [2].
2.1.2. Dye Laser
The dye laser is a Sirah Precision Scan SL Dye Laser. A simplified diagram of the dye laser is
shown in Figure 3.
27
Figure 3 – Sirah Dye Laser schematic, adapted from [1].
The dye laser works on similar principles as the pump laser except that the dye laser cannot
generate its own beam and thus is dependant on an external source. However, dye lasers are
very important in fluorescence studies because of their ability to selectively emit a specific
wavelength. This output wavelength needs to be tunable in order to excite certain quantum
transitions of the intermediate species under study, causing them to fluoresce. Dye lasers use
liquids as a lasing medium because they generate a much broader range of wavelengths when
compared to solid mediums like an Nd:YAG [1].
When the pump beam exits the Nd:YAG it is reflected 180° upward by two mirror boxes and
into the dye laser. The pump beam passes through the first beam splitter, M1, where a small
portion of the beam’s power is diverted toward the 20 mm dye quartz cell. This portion of the
beam stimulates the dye and causes it to fluoresce. Take for example Coumarin 153, shown in
Figure 4. When this dye solution is stimulated by a pump beam at 355 nm, it fluoresces within
the range and efficiencies shown.
28
Figure 4 – Excitation spectrum of Coumarin 153 using a 355 nm pump [3].
A fundamental wavelength can be selected out of this broad spectrum by the use of the prism
expander (PE) and the mirror/gratings G1 and G2, see Figure . The section of the dye laser (the
20 mm dye quartz cell, PE, G1 and G2) makes up the Resonator. Once the beam is generated in
the Resonator, it passes through a series of polarizing plates called Brewster Plates, a turning
prism and then reflected back into the same 20 mm dye quartz cell. As this happens, the
remainder of the beam passes through M1, is reflected by 2 turning prisms and passes through a
second beam splitter, M4. Another small portion of the beam is reflected onto the 20 mm dye
quartz cell as the large majority of the original pump beam passes through M4. The secondary
split beam intersects the beam from the Resonator (that was reflected back into the dye quartz
cell) causing stimulated emission. This action amplifies the beam by a small amount and is
called the Preamplifier [3].
The preamplified beam that is emitted from the 20 mm dye quartz cell is expanded through a
telescope and enters the 40 mm dye quartz cell where the beam is intersected yet again.
However, the remaining 75% of the pump beam’s original power is incident on the 40 mm dye
quartz cell and results in the final amplification of the dye laser beam. This dye quartz cell is the
Main Amplifier. The final beam passes through three more devices before finally exiting the
laser housing. The first device is the Frequency Conversion Unit (FCU), which doubles the
29
frequency and halves the wavelength of the fundamental beam. The compensator steers the
beam back to its original path after it has passed through the FCU. Lastly, a wavelength
separation unit, comprised of four Pellin-Broca prisms, diverts the residual fundamental beam
onto a beam dump to ensure that only the second harmonic passes through and exits the dye laser
[3].
2.1.3. Camera
The camera used in this research is specially designed to image photons emitted from fluoresced
species. The LaVision NanoStar camera is an intensified charge-coupled device (ICCD) camera
of which the basic operation is explained in [1]. The lens currently installed on the camera does
not have any direct magnification capability and can only be focused between roughly 2.5 and 15
feet. To “zoom,” the whole camera must be physically moved. The lens’ focus range therefore
limits the distance between the camera and the combustion event, which directly affects the
camera’s zoom and thus the size of the imaged object.
2.1.4. Combustion Facilities of PLIF System
The experimental apparatus used to generate combustion events are described. The combustion
system includes the combustion vessel, where combustion occurs, the gas manifold system
which is used to fill the combustion vessel with the appropriate fuel-oxidizer mixture, and the
ignition system, which initiates combustion.
The combustion events occurred in a four window constant volume cylindrical vessel diagramed
in Figure9. The four window cylindrical vessel is based on a two window cylindrical vessel used
for imaging flame structure in a shadowgraph system. It is constructed of 316 SS and measures
13.5 cm in diameter and 13 cm long. Two large Pyrex windows provide a line of sight through
the vessel and allow the combustion event to be imaged by the Nanostar camera. Two smaller
windows allow the experimental laser sheet to pass into the vessel, through the flame, and out of
the vessel to terminate in the beam dump. The vessel is fitted with spark electrodes which are
used to create center point ignition. It is filled through an evacuated 3 mm tube which connects
the bottom of the vessel to a gas manifold system.
30
Figure 5: Four window cylindrical vessel with spark electrodes
2.1.4.1. Facilities
A general experimental system diagram is given in Figure 10. An experimental recording of a
species concentration is acquired by triggering a charge-coupled device (CCD) camera to take a
picture at the same time that a laser beam pulse is passing through a transient flame in the
constant volume cylindrical vessel. The experimental laser pulse is emitted from a dye laser,
which is pumped by a Nd:YAG laser. The pump beam leaves the Nd:YAG laser, passes through
an open shutter box and is reflected by two mirrors into the dye laser. The dye laser generates
the experimental pulse. This pulse passes through an energy monitor, which is used to monitor
pulse to pulse energy fluctuations. The experimental pulse is next turned into a sheet with set of
sheet optics. The size of the sheet is controlled by truncating the beam with an iris diaphragm.
The beam enters the cylindrical vessel, passes through the combustion event, and terminates in
the beam dump. The CCD camera is triggered by using the Q-switch signal from the control
computer and a set of timing electronics.
31
Figure 6: System overview
2.1.4.2. Control and Data Acquisition Computer
The computer, which runs the LaVision software package, DaVis 7.1.1 is used for all aspects of
the experiment including adjusting the system, acquiring data, and post-processing results. The
LaVision built central processing unit includes a programmable timing unit (PTU). Data
communication lines from the lasers, energy monitor, and camera are input to the computer. A
unique USB dongle is also plugged into the back of the computer and prevents the use of
software on more than one machine at a time. See LaVision software manuals for more
information about this software package [4, 5].
2.1.5. Calibration and Synchronization of the System
in order to measure the concentrations of OH molecule, it is required to calibrate the laser
system. We have calibrated our PLIF system using a flat flame burner with my colleague, Mr
Colin Fredette in Northeastern University combustion lab and more details can be found in his
master thesis [6]. After calibration DaVis, which is a professional software developed in
LaVision company, for laser diagnostics, measures the concentrations of OH radical in different
conditions. Figure 11 shows the results of OH molecule florescence of stoichiometric methane-
air flame. These images are taken on atmospheric pressure and the temperature of the unburned
32
gas is 300 K. This figure demonstrates that the concentration of OH is the highest in flame front
and then after reaching equilibrium condition in the burned gas region its concentration
decreases.
t=0.3 ms t=0.5 ms t=1 ms t=6 ms
10 mm
t=0.3 ms t=0.5 ms t=1 ms t=6 mst=0.3 ms t=0.5 ms t=1 ms t=6 mst=0.3 ms t=0.5 ms t=1 ms t=6 ms
10 mm
Figure 7: OH radical fluorescence in methane/air flames, T = 300K, P = 1 atm, 1
References
[1]. R. Andrews, “Measurement of Hydroxyl (OH) Concentration of Transient Premixed
Methane-Air flames by Planar Laser Induced Fluorescence (PLIF) Method,” M.S. thesis,
Northeastern University, Boston, MA, 2008.
[2]. Spectra-Physics Technical Staff, Pulsed Nd: YAG Lasers User’s Manual, Spectra- Physics,
2002.
[3] Sirah Technical Staff, Sirah Pulsed Dye Laser Service-Manual, LaVision GmbH, 2007.
[4]. LaVision Technical Staff, DaVis 7.1 Software Manual, LaVision GmbH, 2006.
[5]. LaVision Technical Staff, Imaging Tools Software Manual, LaVision GmbH, 2006.
[6]. C. Fredette, “Quantitative Hydroxyl (OH) Concentration Calibration by Use of a Flat
Flame Burner, Thermocouple and Planar Laser Induced Fluorescence (PLIF) System”,
M.S. thesis, Northeastern University, Boston, MA, August, 2009.
33
3. Thermodynamic Properties of Ionized Gases at
High Temperatures
Submitted to Journal of Energy Resources and
Technology
34
3. Thermodynamic Properties of Ionized Gases at
High Temperatures
Kian Eisazadeh-Far1, Hameed Metghalchi1*, and James C Keck2
1: Mechanical and Industrial Engineering Department,
Northeastern University, Boston, Massachusetts 02115, USA, 2: Mechanical Engineering Department, Massachusetts Institute of Technology,
Cambridge, MA 02139, USA
Abstract
Thermodynamic properties of ionized gases at high temperatures have been calculated by a
new model based on local equilibrium conditions. Calculations have been done for nitrogen,
oxygen, air, argon and helium. The temperature range is 300-100,000 K. Thermodynamic
properties include specific heat capacity, density, mole fraction of particles, and enthalpy.
The model has been developed using statistical thermodynamics methods. Results have been
compared with other researchers and the agreement is good.
Keywords: thermodynamic properties, ionized gases, high temperature, plasma
1* Corresponding Author:
Mechanical and Industrial Engineering
334 Snell Engineering Center, Northeastern University
360 Huntington Avenue, Boston, MA 02115, USA
Tel: (617) 373-2973
Fax: (617) 373-2921
E-mail: [email protected]
35
3.1. Introduction
The purpose of this paper is to provide the thermodynamic properties of nitrogen, oxygen,
air, argon, and helium at high temperatures. These properties are needed for the study of spark
discharges where the electrical energy is deposited in a small kernel and converted to thermal
energy in the gas. This is a high temperature process leading to the formation of plasmas with
very high degrees of ionization. The initial processes and the mechanisms of plasma kernel
formation are beyond the scope of this paper and more details can be found in other references1-
5. However, as the electrical energy is converted to the thermal energy, the temperature of the
plasma increases rapidly and the kernel grows. It is to calculate this growth process that the
thermodynamic properties of the plasma, in particular the specific heat capacity at constant
pressure, are needed.
Prior calculations of the thermodynamic properties of high temperature plasmas have been
carried out by several investigators using a variety of models. Capitielli et al6 have calculated
the thermodynamic properties of air at high using empirical correlations. They calculated the
specific heat capacity, density, molecular weight, thermal conductivity, viscosity, entropy,
enthalpy, and mole fraction of species over the temperature range 50,000 to 100,000K.
Giordano et al7 have calculated the thermodynamic properties using statistical mechanical
methods. Yos8 calculated the transport properties of air and its constituents in the temperature
range 300-30,000 K. Sher et al9 studied the birth of spark channels. For this purpose they
calculated the specific heat capacity and mole fractions of the air at high temperatures using a
simplified thermodynamic model but their results are not very accurate. Other studies
performed in last few decades include: Behringer et al10, Jordan and Swift11, Kopainsky12,
Pateyron et al13. Most of these calculations cover the properties up to 50,000 K. However, for
plasmas other than air, such as the inert gases helium and argon, the available data in
temperature range up to 100,000 K is limited.
In this paper, we present a new model based on statistical mechanics which is both simple
and accurate. Calculations have been made for nitrogen, oxygen, air, argon, and helium. The
temperature range is 300-100,000 K at constant atmospheric pressure. The calculated properties
include specific heat capacity, density, enthalpy, and the number of particles. Results have been
compared with existing prior data and where the conditions overlap the agreement is generally
good.
36
3.2. General Model
The general model is based on statistical thermodynamic methods and it is assumed that the
species are in thermodynamic equilibrium. The physical constants of the ions and species are
taken from Fay14 and Moore15. For nitrogen, oxygen, and air the considered species are N2, N,
N+, N2+, N3+, N4+, N5+, N6+, O2, O, O+, O2+, O3+, O4+, O5+, O6+, O7+, and e (electron). In addition
to nitrogen, oxygen, and air plasma the properties of two inert gases, argon and helium, have
been studied as well. The assumed species for argon are Ar, Ar+, Ar2+, Ar3+, Ar4+, Ar5+, and Ar6+
and for helium are He, He+, and He2+.
We assume a diatomic gas at low temperatures. The number of elemental atom number is
then given by
z
AAEA0
22
ε = 0, 1, 2, 3 …z
(1)
where ε is the charge number of the ions.
Total number of moles is given by
z
A AeAM0
2
(2)
Assuming charge neutrality, the mole number of free electrons is given by
z
Ae0
(3)
The equation of state is:
pV=MART (4)
where p is the pressure, V is the volume, R is the universal gas constant, and T is the
temperature.
3.2.1. Dissociation
For a dissociation reaction
37
dHAA 22 (5)
dH is the dissociation enthalpy. The equilibrium constant based on concentration is defined
by
VA
AKed
2
2
(6)
Using eq 4 to eliminate V in eq 6 we obtain
p
K
p
RTK
MA
A pded 2
2
(7)
At low temperature there are no ions ( 0e ) and eqs 1 and 2 reduce to
2/)(2 AEAA (8)
2/)( AEAM A (9)
Substituting eqs 8 and 9 in eq 7 we will have:
22 14 yyBd (10)
where
EAAy / (10.1)
pdd KpB / (10.2)
and Kpd is the equilibrium constant based on pressure.
Solving eq 10 we obtain
2
1
0 )41(
dBy (11)
Where
38
z
yy0
0
(12)
From eqs 8 and 9
2
1 022
y
EA
Ay
(13)
Figure 1 shows the variation of y0, y2, and MA/EA for nitrogen dissociation. The normalized
number of moles MA /EA, increases due to dissociation of the molecule to atoms. The
concentration of y must decrease at higher temperatures due to ionization. In next section,
ionization process will be described to complete the predictions.
3.2.2. Ionization Process
The governing equations for ionization will now be described.
For a typical ionization reaction
HeAA 1 ε = 0, 1, 2, 3 …z (14)
H is the ionization enthalpy. The equilibrium constant based on concentration is given by
VA
eAKei 1
(15)
Using eq 4 to eliminate V in eq 15 we obtain
p
K
p
RTK
MA
eA piei 1
(16)
The number of elemental atoms involved in reaction (14) is:
AAEA 1 (17)
The total mole numbers is:
eEAM A (18)
39
The number of moles of electrons is:
AAe 1)1( (19)
Combining eqs 17-19 we obtain
AEAA 1 (20)
AEAM A (21)
AEAe )1( (22)
Substituting eqs 20-22 in eq 16 then gives
01
)1()( 2
B
yy (23)
Solving this second-order equation, we find
)}1(]1
4)1{[(
2
1 2
12
0
By
(24)
zyyyy ...10
(25)
100 yyy 26)
It can be seen in eq 25 that 0y involves the potential concentration of other ions in upper
levels; so it increases and eventually reaches unity. The actual concentration of y is achieved
by correcting 0y in eq 26 by taking into account the effect of next ionization. Figure 2 shows
the variations of y , 0y and 1
0y versus temperature during the ionization process. The physical
basis of this model is that ionization is an endothermic process and the progress of each
reaction requires additional energy. Therefore it can be assumed that ionization is a step by
step process and the level of ionization increases with temperature. Figure 3 shows the sketch
of this model. The calculations are performed in parallel and the individual packages are in
mutual equilibrium. The starting point is the bottom package (A2↔2A). The normalized mole
fraction of A versus elemental number of nitrogen atoms is entered to the next package and the
40
calculations proceed; in the next package the output will be A+ and the same pattern flows to
the next ones. In each package, thermodynamic equilibrium calculations are performed and the
concentration of each species is computed. The mole fractions of species are normalized by the
elemental number of atoms to ensure the conservation of mass. Given the temperature, pressure
and composition all the thermodynamic properties of the plasma can be calculated.
The enthalpy is defined as:
z
AA AThAThH0
2 )()(2
(27)
where )(2
ThA is the enthalpy of molecule A2 , and hε(T) is the enthalpy for specie Aε.
Normalized enthalpy will be:
z
AAA yThyTh
EA
H
02 )()(
2
(28)
Heat capacity of the mixture is defined by:
)()/
(0
22 T
yhy
T
h
T
yhy
T
h
T
EAH
EA
cA
zA
AA
pApA
(29)
cp is the combination of translational, rotational, vibrational, and electronics energy modes. It is
defined by:
lvibrationaprotationalpnaltranslatiopp cccc )()()( + selectronicpc )( (30)
An important feature of this model is that the properties of the individual ion packages are
first calculated and then coupled to form the system of packages. This flexibility permits a wide
range of conditions to be covered by just one generic set of equations. For example, the model
can treat the system of oxygen plasma, nitrogen plasma, and air plasma simultaneously.
3.3. Results and Discussion
Figure 4 and 5 show the mole fractions of oxygen and nitrogen plasma up to 100,000 K. the
mole fractions in these two figures are defined by:
41
EA
M
EA
Ax A
A/
for monatomic species and
EA
M
EA
Ax A
A /22
for molecule (31)
It can be seen that for both atoms, one dissociation and five ionizations (N5+ and O5+) occur.
The onset of ionization occurs around 6000 K and as the ionization proceeds, the mole fraction
of species decrease. This is due to the increasing mole fraction of electrons. Figure 6 and 7
show the mole fractions of argon and helium.
Figure 8 shows the mole fractions of air plasma. The peaks of this figure correspond to those
in figures 4 and 5.
Figure 9 shows normalized particle numbers of oxygen, nitrogen, air, argon, and helium
versus temperature. The particle numbers have been normalized by the elemental number of
atoms. It can be seen that under constant pressure condition, the number of particles increase
dramatically. It shows the effect of ionization and increasing number of electrons. It is seen that
the level of ionization determines the number of particles. Since in helium there are just two
electrons, the number of particles does not increase as much as for other species.
Figure 10 shows specific heat capacities of oxygen, nitrogen, air, argon, and helium versus
temperature. The several peaks at this figure represent the reactions and production of atoms
and ions, which increase the heat capacity of the system. For oxygen and nitrogen molecules
the role of rotational and vibrational energy modes on heat capacity is important at lower
temperatures. However, after dissociation, the only energy mode of each species is translational
and electronic and the increase in the heat capacity is just due to the ionization and the change
of species concentration as can be seen in eq 29.
A comparison between figures 4-8 and figure 10 shows that the peak values of heat
capacities correspond to the stage where the rate of dissociation and ionization is maximum.
For example for air, first two peaks represent the equilibrium reaction of oxygen and nitrogen
molecules and atoms and the rest of peaks correspond to the ionization reactions. Since there
are just two ionization reactions in helium, consequently, only two peaks are observed in the
figure. The behavior of this figure can be understood by the terms appeared in eq 29.
Figure 11 shows enthalpies of oxygen, nitrogen, air, argon, and helium versus temperature.
At higher temperatures the enthalpy of helium exceeds the enthalpy of air. This is due to the
higher heat capacity of helium at higher temperatures.
42
3.4. Comparison with Other Calculations
Figure 12 shows values of specific heat and the comparison with the results of Capitielli and
coworkers6, Sher et al9 and STANJAN equilibrium code16 in temperature range of 300-5000 K.
Except for Sher et al, the agreement is good. In this range of temperature the concentration of
ions is almost zero and the increase in heat capacity is due to the excitement of the vibrational
energy modes and dissociation of oxygen atom.
Figure 13 compares the heat capacities of air calculated in this study with those of Capitielli
and Sher over the temperature range 300-100,000 K. This figure shows good agreement with
the results of Capitelli up to 70,000 K. Beyond 70,000 K, Capitielli et al underestimates the
heat capacity due to the neglect the N5+ and O5+ ions in their study. Sher’s results are limited to
low temperatures are in poor agreement with the others
References
[1]. Bradley, D., Sheppard, C.G.W., Suardjaja, I.M., Woolley, R. Fundamentals of high-
energy spark ignition with lasers. Combustion and Flame 2004, 138, Issues 1-2, 55-77.
[2]. El-Koramy, R.A., Effendiev, A.Z., Aliverdiev, A.A. The peculiarities of spark channel
formation in air gas at atmospheric pressure. Physica B: Condensed Matter 2007, 392,
Issues 1-2, 304-308.
[3]. Kravchik, T., Sher, E. Numerical modeling of spark ignition and flame initiation in a
quiescent methane-air mixture. Combustion and Flame 1994. 99, Issues 3-4, 635-643.
[4]. Maly, R. Ignition model for spark discharges and the early phase of flame front growth.
Symposium (International) on Combustion 1981, 18, Issue 1, 1747-1754.
[5]. Schäfer, M., Schmidt, R., Köhler, J. I-D simulation of a spark discharge in air.
Symposium (International) on Combustion 1996, 26, Issue 2, 2701-2708.
[6]. Capitelli, M., Colonna, G., Gorse, C., D’Angola, A. Transport properties of high
temperature air in local thermodynamic equilibrium. Eur. Phys. J. D 2000, 11, 279-289.
[7]. Giordano, D., Capitelli, M., Colonna, G., Gorse, C., (1994) ESA STR-237.
[8]. Yos, J.M., 1963 AVC-RAD-TM 63-7.
[9]. Sher, E., Ben-Ya'Ish, J., Kravchik, T. On the birth of spark channels. Combustion and
Flame 1992, 89, Issue 2, 214-220.
43
[10]. Behringer, K., Kollmar, W., and Mentel, J. Messung der Wärmeleitfähigkeit von
Wasserstoff zwischen 2000 und 7000 °K. Z. Phys 1968. 215, 127.
[11]. Jordan, D., and Swift, J.D. Measurement of thermal conductivity of argon-nitrogen gas
mixtures at high temperatures. Int. J. Electron 1973. 35, No. 5, 595-608.
[12]. Kopainsky, J. Strahlungstransportmechanismus und Transportkoeffizienten im Ar-
Hochdruckbogen. Z. Phys 1971 Vol. 248, issue 5, 417.
[13]. Pateyron, B., Elchinger, MF, Delluc, G., and Fauchais, P. Thermodynamic and transport
properties of Ar–H2 and Ar–He plasma gases used for spraying at atmospheric pressure.
Plasma Chem. Plasma Process 1992, 12, No. 4, 421-448.
[14]. Fay, J. Molecular Thermodynamics; Allison-Wesley Inc, 1965.
[15]. Moore, C. E., Atomic Energy Levels, 1971 Vol. 1, U.S. Dept. of Commerse, National
Bureau of Strandards, NSRDS-NBS 35.
[16]. STANJAN Interactive Computer Programs for Chemical Equilibrium Analysis, WC
Reynolds, Stanford University, 1980.
44
T(K)
y
10000 20000 300000
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
1.1
y2
y0
MA/EA
Figure 1: the variation of y0, y2, and MA/EA versus temperature during the dissociation
process
45
T(K)
y
20000 40000 60000 800000
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
y0
y=y0-y0
+1
y0+1
Figure 2: variation of 0y , 1
0y and y versus temperature during the ionization process
46
Figure 3: the sketch of equilibrium packages
AA 22
eAA
eAA 2
eAA 32
eAA 43
eAA 54
eAA 65
T
A
A
2A
3A
4A
5A
47
T(K)
x
20000 40000 60000 80000 100000
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
O2
O
O+
O2+
O3+
e
O4+ O5+
Figure 4: mole fractions of oxygen species versus temperature
48
T(K)
x
20000 40000 60000 80000 100000
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1 N2
N
N+
N2+
N3+
N4+
e
N5+
Figure 5: mole fractions of nitrogen species versus temperature
49
T(K)
x
0 20000 40000 60000 800000
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
Ar
Ar+
Ar2+
Ar3+
Ar4+
Ar5+
e
Figure 6: mole fractions of argon plasma versus temperature
50
T(K)
x
20000 40000 60000 80000 1000000
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
He
He+
e
He2+
Figure 7: mole fractions of helium plasma versus
51
T(K)
x
20000 40000 60000 80000 100000
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
N2
O2
N
O
N+
O+
N2+
O2+
N3+
O3+
N4+
e
O4+
N5+
O5+
Figure 8: mole fractions of air species versus temperature
52
T (K)
No
rma
lize
dp
art
icle
nu
mb
ers
25000 50000 75000 1000000
3
6
9
12
15AirArgonOxygenNitrogenHelium
Figure 9: Plasma particle numbers normalized by elemental atom numbers
53
T(K)
c p(k
J/km
ol.K
)
20000 40000 60000 80000 1000000
50
100
150
200
250
ArgonHelium
(a)
T(K)
c p(k
J/km
ol.K
)
20000 40000 60000 80000 1000000
50
100
150
200
250
300
350
400
450
AirOxygenNitrogen
(b)
Figure 10: Heat capacities of oxygen, nitrogen, argon, and helium versus temperature
a: helium and argon, b: air, oxygen, and nitrogen
54
T (K)
Ln
(hkJ
/kg
)
25000 50000 75000 100000-15
-10
-5
0
5
10
15
HeliumArgon
(a)
T (K)
Ln
(hkJ
/kg
)
25000 50000 75000 100000-15
-10
-5
0
5
10
15
AirOxygenNitrogen
(b)
Figure 11: enthalpies of different species versus temperature
a: argon and helium, b: air, oxygen, nitrogen
55
T(K)
c p(k
J/kg
.K)
0 1000 2000 3000 4000 50000
1
2
3
4
5
6
Capitielli et al6
Sher et al9
STANJAN equlibrium code16
present study
Figure 12: heat capacity of air versus temperature and comparison with other researchers
(300-5000 K) , ref 6; , ref 9; , ref 16; , present study
56
T(K)
c p(k
J/kg
.K)
0 20000 40000 60000 80000 1000000
5
10
15
20
25
30
35
40
45
50
Capitielli et al6
Sher et al9
present study
Figure 13: heat capacity of air versus temperature and comparison with other researchers
(300-100,000 K), , ref 6; , ref 9; , present study
57
4. A Thermodynamic Model for Argon Plasma
Kernel Formation
Submitted to International Journal of Thermodynamics
58
4. A Thermodynamic Model for Argon Plasma
Kernel Formation
Kian Eisazadeh-Far1*, Farzan Parsinejad2, Hameed Metghalchi1 and
James C. Keck3
1: Northeastern University, Mechanical and Industrial engineering Department, Boston, MA 02115
2: Chevron Oronite Company LLC, Richmond, CA 94801
3: Massachusetts Institute of Technology, Cambridge, MA 02139
Abstract
Plasma kernel formation of argon is studied experimentally and theoretically. The
experiments have been performed in a constant volume cylindrical vessel located in a
shadowgraph system. The experiments have been done in constant pressure. The energy of
plasma is supplied by an ignition system through two electrodes located in the vessel. The
experiments have been done with two different spark energies to study the effect of input
energy on kernel growth and its properties. A thermodynamic model employing mass and
energy balance was developed to predict the experimental data. The agreement between
experiments and model prediction is very good. The effect of various parameters such as
initial temperature, initial radius of the kernel, and the radiation energy loss have been
investigated and it has been concluded that initial condition is very important on formation
and expansion of the kernel.
Keywords: Argon plasma, kernel formation, thermodynamic model, ionization
4.1. Introduction
Since plasma kernel is the beginning of flame propagation process in many systems,
understanding of this process is very important. In plasma kernel formation of a non-combustible
gas by an external energy source like spark, there are two important processes involved in the
59
phenomena: The first part of plasma formation which is very short (microseconds) is formation
of spark channel between two electrodes, and the second part which is longer (milliseconds) is
absorbing most of electrical energy and beginning the ionization and plasma kernel expansion. In
the case of existence of a combustible gas, the third stage will be evolution of plasma kernel to a
self sustained flame.
There have been some theoretical and experimental researchers who investigated first and
third stages (Maly (1981), Ziegler et al (1985), Lee et al (2000), Pischinger and Heywood
(1991), Mantel (1992), Kravchik and Sher (1994), Sher et al (1992), Sher and Keck (1986),
Bradley et al (2004), Yossefi et al (1993)). Maly and Vogel (1979) in a theoretical and
experimental study determined that the most important component of spark discharge is the
breakdown process. They mentioned that the other processes including arc and glow discharge
are less important because their electrical energy is dissipated into the electrodes. Sher et al
(1992) did a fundamental study on spark formation in air and proposed a model to calculate the
spark kernel temperature after breakdown. They concluded that the initial spark kernel is a very
high temperature region, but the temperature drops rapidly due to energy dissipation. They
determined that beyond a specific limit, the energy of the spark affects only the initial flame
kernel radius, and not the temperature. They concluded that the spark kernel is grown in two
steps. The first, shorter stage consists of a pressure wave emission. This is followed by a longer
period, in which diffusion occurs. Chen and Ju (2007) studied the evolution of the ignition kernel
to a flame ball and they concluded that radiation plays a very important role in transition of
initial flame kernel to the actual self-sustained flame.
Most of the cited research focus on first and third stage of ignition and a semi quantitative
understanding of them has been achieved. In this paper we will focus on second part of ignition
which is formation and expansion of the plasma kernel by adding electrical energy. We will
study plasma kernel of an inert gas, argon, to avoid the complexities of reacting gas mixture and
existence of multiple species.
4.2. Experimental System
The experimental system includes a cylindrical vessel. It is fitted with two extended spark
plug electrodes which provide a central point ignition source for the chamber. The thickness of
electrode (de) is 0.381 mm. A shadowgraph system is used with cylindrical system to take
60
images from kernel growth. A CMOS camera with the capability of taking pictures up to 40,000
frames per second has been used in these experiments. A computer driven system has been used
to prepare the initial condition. Figure 1 shows the sketch of the experimental system. Additional
information about the experimental facility can be found in previous publications (Rahim et al
(2008), Eisazadeh-Far et al (2010), Eisazadeh-Far et al (2010), Parsinejad et al (2006) and
Parsinejad et al (2007)).
Ignition system: An important detail of the ignition system is the 5 select-switch, which
allows the energy stored in the capacitors to be varied. The capacitors storing this energy
discharge to a transformer and therefore to spark plugs. Voltage and current across the spark plug
gap during the electrical discharge have been measured to calculate the discharge energy. This
has been achieved by setting up a detection circuit employing two resistors. The resistors are
placed in parallel to the spark plugs to allow only a very small but measurable portion of the
current to flow through the detection circuit. These small portions were then sampled by an
oscilloscope. In this system the voltage difference across one of the resistors in the detection
circuit is 1/201 of the voltage across the spark plugs. Another similar method was used to
calculate the current across the spark plug, which in this case is exactly equal to amperage
flowing through the parallel circuit.
4.3. Experimental Results
4.3.1. Discharge Energy
Using a voltage divider circuit, the voltage and current across the gap were measured. Figure 2
shows the experimentally determined voltages and currents across the spark plug gap for each
voltage setting on the ignition system in argon. The spike, approximately at 5-10 microsecond in
duration, shows the breakdown stage which is the beginning of spark discharge. In this stage the
gap is bridged by the avalanche of electrons flowing from cathode to anode.
Figure 3 shows the discharged power calculated by product of measured values of current
and voltage for two different stored energies in the ignition system. Discharged energy, DE, can
be calculated having by DE=∫VI dt. It should be noted that discharged energy is different from
the electrical energy converted to the thermal energy in the gas. A portion of the discharged
energy is dissipated by conduction into the electrodes.
61
4.3.2. Image Capturing
Figures 4 shows the snapshot of argon plasma kernel. It can be seen that the boundary layer
surrounding the plasma kernel is vey thin. Figure 5 shows the radii of kernel at two different
spark energies. It can be seen that spark energy has a remarkable effect on the size of the kernel.
4.4. Thermodynamic Model
In this section the thermodynamic model for the predicting the growth of argon plasma
kernel will be described. Figure 6 shows the schematic diagram of the control mass and energy
transformation across the boundary.
The major assumptions are as following:
1- It is assumed that the plasma kernel is spherical.
2- All calculations start after breakdown stage. It is assumed that the shock wave is emitted
and pressure is constant.
3- Since the relaxation time scale of different energy modes (translational, rotational,
vibrational, electronic) are too small (O~10-9 s), all species are in local thermodynamic
equilibrium (Maly (1981), Sher et al (1992), Sher and Keck (1986), and Maly and Vogel (1979)).
4- There are no mass transport processes involved in the model. It is assumed that the
plasma kernel is a constant-mass system and expands in a constant pressure process.
5- Energy losses are due to radiation, cathode-anode fall dissipations, and conduction
through thermal boundary layer to the electrodes.
The governing equations are, equation of state, and mass conservation, and energy balance.
The equation of state is given as
pV =nRT (1)
where p is the pressure, V is the volume of kernel, n is number of moles, R is the universal gas
constant, and T is the temperature. Total number of moles is determined by:
z
iinn
1
(2)
where z is the number of species.
62
The number of elemental atom number is then given by
z
ArEAr0
ε = 0, 1, 2, 3,…z (3)
In this equation, ε is the charge of ions.
The equation for energy balance is given by:
condradv QQVVpDETTnc )()( 00 (4)
Equation (4) can be rewritten as:
condradp QQDEVVp
R
c )( 0 (5)
where T is the temperature, cv and cp are the heat capacities, 0V is the initial volume of the
kernel, Qrad is the radiation energy loss, and Qcond is the conduction energy loss to the electrodes
by thermal boundary layer.
In equation (5):
SEQIVdtdtIVdtIVIVdtDE ca
bt
b col
t
b fall
b 00
)()( (6)
In this equation, caQ is the cathode-anode fall dissipation by conduction into the electrodes, and
SE is the net spark energy converted to thermal energy in the plasma.
Conduction to electrodes in the thermal boundary layer is:
dtdr
dTAkQ eTcond )( (7)
where
t (8)
as the thermal boundary layer thickness. Equation (7) can be rewritten as:
dtt
TTAkQ eT
cond )( 0 (9)
In this equations (7-9), kT is the thermal conductivity of the gas; Ae is the contact area of
63
electrodes with the gas, T0 is the temperature of the electrode, and is the thermal diffusivity of
argon. Experimental data of Wilbers et al (2002), which have been collected at high temperatures
under optically thin conditions, have been used to model radiation losses.
4.4.1. Thermodynamic Properties
the thermodynamic properties of argon have been calculated by statistical thermodynamic
methods. These parameters include cp and the enthalpy of the mixture. For argon the species are
Ar, Ar+, Ar2+, Ar3+, Ar4+, Ar5+, Ar6+and e (electron). Additional information can be found in
(Eisazadeh-Far et al (2010)). In the theoretical model, values of specific heat in needed in very
high temperatures of 300 – 100,000 K. Figure 7 shows the heat capacity of argon in this
temperature range. Figure 8 shows the normalized number of species of argon. The results of
equation (2) have been normalized by the sum of the elemental atom numbers defined in
equation (3). It can be seen that number of particles increase as the temperature of the gas
increases.
4.5. Results and Discussion
Equations 1 though 9 have been used to determine the radii and temperature of plasma
kernel for different initial temperature and volume of the kernel and input electrical energy. The
values of initial radius and initial temperature depend on discharged energy, pressure, gas type
and energy losses during the breakdown. The effect of initial parameters on the size and
temperature of the kernel is investigated in following section.
4.5.1. Initial Radius
Figures 9 and 10 demonstrate the effect of initial radius of the plasma kernel on growth and
temperature of the plasma kernel. It can be seen that the size of plasma kernel is not dependent
on initial radius but the temperature of the kernel is very sensitive to the initial radius.
4.5.2. Initial Temperature
Figures 11 and 12 show the effect of initial temperature on plasma kernel growth and its
temperature. It is shown that initial temperature does not have a major effect on the size of the
kernel but it can change the temperature of the hot plasma strikingly. Initial temperature depends
on breakdown energy and its duration. The range of initial temperature for plasma is 5,000-7,000
K.
64
4.5.3. Result of Calculations
Table 1 shows the values of the initial condition. Figure 13 shows the results of the calculations
and the comparison with the experiment. There are two curves in each figure which are the
calculations with and without radiation. As it can be seen radiation is a major source of energy
losses. The radiation becomes important especially when temperature is high. It can also be
concluded that the decrease of argon plasma radii is due to radiation energy losses. In higher
discharged energies not only the temperature of the kernel but also the area of kernel increases
and it causes higher radiation energy losses.
Table 1: initial conditions for calculations
Argon (DE = 26 mJ) Argon (DE = 46 mJ)
Initial radius (mm) 0.25 0.34
Initial temperature (K) 5000 7000
DE (mJ) 26 46
SE (mJ) 2.2 14.7
Figure 14 shows the fraction of energy terms in argon plasma. It can be seen that a large
part of energy is dissipated by cathode-anode fall conduction dissipations. Clearly, the amount of
radiation loss depends on the value of discharged energy. This percentage is strongly a function
of current and the temperature of the arc (Hermann and Schade (1970)). Another important
source of energy loss is the radiation from hot gas. Figure 14 shows that in higher discharged
energies, the amount of radiation energy losses are higher, which is due to larger surface area of
the kernel and higher temperature of the plasma kernel. Figure 14 shows that just about 3-5 % of
discharged energy is converted to thermal energy. This result is in good agreement with
experimental measurements of Teets and Sell (1988).
65
Table 1: Summary of fractional energy terms
Argon (DE = 26 mJ) Argon (DE = 46 mJ)
cathode-anode fall losses 88.80% 68.20%
thermal boundary layer conduction 0.20% 0.30%
radiation losses 6% 27%
converted to thermal energy (present study) 5% 3.50%
converted to thermal energy (Teets and Sell (1988)) 7%
Acknowledgment
This work has been partially supported by Office of Naval Research (ONR), grant number
N00010-09-1-0479, under technical monitoring of Dr. Gabriel Roy.
References
Bradley, D., Sheppard, CGW, Suardjaja, IM., Woolley, R., 2004, “Fundamentals of high-energy
spark ignition with lasers”, Combustion and Flame, Volume 138, Issues 1-2, p. 55-77.
Chen, Z., and Ju., Y., 2007, “Theoretical analysis of the evolution from ignition kernel to flame ball and planar flame”, Combustion Theory and Modeling, Vol. 11, Issue 3 , p. 427 - 453
Eisazadeh-Far, K., Metghalchi, H., and Keck, JC., 2010, “Thermodynamic Properties of Ionized Gases at High Temperatures”, Submitted to Journal of Energy Resources and Technology.
Eisazadeh-Far, K., Parsinejad, F., and Metghalchi, H., 2010, “Flame structure and laminar
burning speeds of JP-8/air premixed mixtures at high temperatures and pressures”, Fuel, Vol. 89,
p.1041–1049.
Eisazadeh-Far, K., Moghaddas, A., Al-Mulki, J., Metghalchi, H., 2010, “Laminar Burning
Speeds of Ethanol/Air/Diluent Mixtures”, Accepted in 33rd Symposium (International) on
Combustion.
Hermann, W., and Schade, E., 1970, “Transportfunktionen von Stickstoff bis 26000 K”, A.
Physik 233, 333-350.
Kravchik, T., Sher, E., 1994, “Numerical modeling of spark ignition and flame initiation in a
quiescent methane-air mixture”, Combustion and Flame, Volume 99, Issues 3-4, p. 635-643
Lee, YG., Grimes, DA., Boehler, JT., Sparrow, J., and Flavin, C., 2000, “A Study of the Effects
of Spark Plug Electrode Design on 4-Cycle Spark-gnition Engine Performance”, SAE paper
66
2000-01-1210.
Maly, R., Vogel, M., 1979, “Initiation and propagation of flame fronts in lean CH4-air mixtures
by the three modes of the ignition spark”, Symposium (International) on Combustion, Vol. 17,
Issue 1, p. 821-831.
Maly, R., 1981, “Ignition model for spark discharges and the early phase of flame front growth”,
Symposium (International) on Combustion, Vol. 18, Issue 1, p.1747-1754.
Mantel, T. 1992, SAE Paper 920587.
Parsinejad, F., Arcari, C., Metghalchi, H., 2006, “Flame Structure and Burning Speed of JP-10
Air Mixtures”, Combustion Science and Technology, Vol 178, 975-1000.
Parsinejad, F., Keck, JC., and Metghalchi, H., 2007, “On the location of flame edge in Shadowgraph pictures of spherical flames: a theoretical and experimental study”, Vol. 43, Number 6, 887-894.
Pischinger, S., Heywood, JB., 1991, “A model for flame kernel development in a sparkignition engine”, Symposium (International) on Combustion, Vol 23, Issue 1, p. 1033-1040.
Rahim, F., Eisazadeh-Far, K., Parsinejad, F., Andrews, RJ., Metghalchi, H., 2008, “A Thermodynamic Model to Calculate Burning Speed of Methane-Air- Diluent Mixtures”, International Journal of Thermodynamics, Vol. 11, p.151-161.
Sher, E., Keck, JC., 1986,“Spark ignition of combustible gas mixtures”, Combustion and Flame, Volume 66, Issue 1, p. 17-25.
Sher, E., Ben-Ya'Ish, J., Kravchik, T., 1992, “On the birth of spark channels”, Combustion and
Flame, Volume 89, Issue 2, p. 214-220
Song, J. and Sunwoo, M., 2000, “A Modeling and Experimental Study of Initial Flame Kernel
Development and Propagation in SI Engines”, SAE paper 2000-01-0960.
Teets, RE., and Sell, JA., 1988, “Calorimetry of Ignition Sparks”, SAE Paper 880204.
Wilbers, A.T.M., Beulens, J.J., and Schram, D.C., 2002, “Radiative energy loss in a two-
temperature argon plasma”, Journal of Quantitative Spectroscopy and Radiative Transfer, Vol.
46, Issue 5, p. 385-392.
Yossefi, D., Belmont, R., Thurley, R., Thomas, JC., Hacohen, J., 1993, “A Coupled
Experimental-Theoretical Model of Flame Kernel Development in a Spark Ignition Engine”,
SAE paper 932716.
67
Ziegler, G.FW., Wagner EP., Maly, R., 1985, “Ignition of lean methane-air mixtures by high
pressure glow and ARC discharges”, Symposium (International) on Combustion, Volume 20,
Issue 1, p. 1817-1824.
Figure 1: the experimental set up of the system
68
Time (ms)
Vo
ltag
e(V
)
0 0.5 1 1.5 2 2.50
100
200
300
400
500
600
700
800
900
1000
1100
1200
DE = 46 mJ
DE = 26 mJ
Breakdown mode: 0.25 mJ
Time (ms)
curr
en
t(A
)
0 0.5 1 1.5 2 2.50
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
0.45
0.5
DE = 46 mJ
DE = 26 mJ
Figure 2: Voltage and current versus time for high and low energy: Argon
69
Time (ms)
Po
we
r(W
)
0 1 2 30
10
20
30
40
50DE = 26 mJDE = 46 mJ
Figure 3: Spark discharge power of argon at low and high energies
Figure 4: Argon plasma kernel, P = 1 atm, DE = 46 mJ
70
Time (ms)
r(m
m)
0 0.5 1 1.50
0.5
1
1.5
argon, DE = 46 mJ
argon, DE = 26 mJ
Figure 5: argon radii at two different spark energies (DE = 26 and 46 mJ)
Figure 6: the sketch of the model
71
Temperature (K)
c p(k
J/kg
.K)
20000 40000 60000 80000 1000000
5
10
15
20
25
30
Figure 7: Specific heat capacity of argon at high temperatures
T (K)
No
rma
lize
dp
art
icle
nu
mb
ers
25000 50000 75000 1000000
3
6
9
12
15
Figure 8: particle numbers of argon normalized by elemental atom numbers
72
Time (ms)
r(m
m)
0 0.5 1 1.5 2 2.5 30
0.5
1
1.5
2
2.5
ri = 0.32 mmri = 0.34 mmri = 0.38 mm
Figure 9: The effect of initial radius on kernel size of argon,
Ti = 7000 K, DE = 46 mJ, Qrad = 0
Time (ms)
Te
mp
era
ture
(K)
0 0.5 1 1.5 2 2.5 30
10000
20000
30000
40000
50000
60000
70000
80000
90000
100000
110000
ri = 0.32 mmri = 0.34 mmri = 0.38 mm
Figure 10: The effect of initial radius on kernel temperature of argon,
Ti = 7000 K, DE = 46 mJ, Qrad = 0
73
Time (ms)
r(m
m)
0 0.5 1 1.5 2 2.5 30
0.5
1
1.5
2
2.5
Ti = 5000 KTi = 6000 KTi = 7000 K
Figure 11: the effect of initial temperature on argon kernel growth,
Ti = 7000 K, ri = 0.34 mm, DE = 46 mJ, Qrad = 0
Time (ms)
Te
mp
era
ture
(K)
0 0.5 1 1.5 2 2.5 30
20000
40000
60000
80000
100000
120000
Ti = 5000 KTi = 6000 KTi = 7000 K
Figure 12: the effect of initial temperature on argon kernel temperature,
Ti = 7000 K, ri = 0.34 mm, DE = 46 mJ, Qrad = 0
74
Time (ms)
r(m
m)
0 0.5 1 1.5 2 2.5 30
0.5
1
1.5
2
2.5
3with radiationzero radiationExperiment
DE = 26 mJ
Ti = 5000 K
ri = 0.25 mm
Qrad = 6% of DE
de = 0.381 mm
(a)
Time (ms)
r(m
m)
0 0.5 1 1.5 2 2.5 30
0.5
1
1.5
2
2.5
3with radiationzero radiationExperiment
DE = 46 mJ
Ti = 7000 K
ri = 0.34 mm
Qrad = 27% of DE
de = 0.381 mm
(b)
Figure 13: argon plasma radii and the comparison with experiments in
a: DE = 26 mJ and b: DE = 46 mJ
75
Figure 14: fraction of energy terms for argon plasma kernel,
a: DE = 26 mJ, b: DE = 46 mJ
76
5. On Flame Kernel Formation and Propagation in
Premixed Gases
Published in Combustion and Flame
Vol. PP. 2010
77
5. On Flame Kernel Formation and Propagation in
Premixed Gases
Kian Eisazadeh-Far1*, Farzan Parsinejad2, Hameed Metghalchi1 and
James C. Keck3
1: Northeastern University, Mechanical and Industrial engineering Department, Boston, MA 02115
2: Chevron Oronite Company LLC, Richmond, CA 94801
3: Massachusetts Institute of Technology, Cambridge, MA 02139
* Corresponding Author:
Mechanical and Industrial Engineering
334 Snell Engineering Center, Northeastern University
360 Huntington Avenue, Boston, MA 02115, USA
Tel: (617) 373-3090
Fax: (617) 373-2921
E-mail: [email protected]
78
Abstract
Flame kernel formation and propagation in premixed gases have been studied experimentally and
theoretically. The experiments have been carried out at constant pressure and temperature in a
constant volume vessel located in a high speed shadowgraph system. The formation and
propagation of the hot plasma kernel has been simulated for inert gas mixtures using a
thermodynamic model. The effects of various parameters including the discharge energy,
radiation losses, initial temperature and initial volume of the plasma have been studied in detail.
The experiments have been extended to flame kernel formation and propagation of methane/air
mixtures. The effect of energy terms including spark energy, chemical energy and energy losses
on flame kernel formation and propagation have been investigated. The inputs for this model are
the initial conditions of the mixture and experimental data for flame radii. It is concluded that
these are the most important parameters effecting plasma kernel growth. The results of laminar
burning speeds have been compared with previously published results and are in good
agreement.
Keyword: flame kernel, plasma, laminar burning speed, spark ignition
5.1. Introduction
An understanding of the spark ignition process is important for the improving the fuel
efficiency and reducing the emissions of IC engines and burners. Prior research carried out over
the past several decades by a large number of investigators [1-21] has shown that the ignition
process involves three distinct stages. The first stage, which occurs on a time scale of
microseconds, involves the formation of a narrow spark channel followed by the formation of an
equilibrium plasma kernel with a radius of approximately 0.5 mm and a temperature of 7000 K.
The second stage, which occurs on a time scale of milliseconds, involves the subsequent growth
of a constant mass plasma kernel of atomic ions and electrons due to the input of additional
electrical energy from the ignition system. The third and final stage involves the ignition of the
combustible gas mixture surrounding the hot plasma kernel to produce a propagating flame. The
first and third stages of this ignition process have been extensively investigated in prior work and
a semi quantitative understanding of them has been achieved. Maly and Vogel [1] in a theoretical
and experimental study determined that the most important component of spark discharge is the
breakdown process. They mentioned that the other processes including arc and glow discharge
79
are less important because their electrical energy is dissipated into the electrodes. Maly [2] and
Ziegler et al [3] studied the formation of lean methane-air flames based on the theories proposed
in [1]. They concluded that the best ignition system is the one with highest level of energy and
shortest time interval. Sher et al [4] did a fundamental study on spark formation in air and
proposed a model to calculate the spark kernel temperature after breakdown. They concluded
that the initial spark kernel is a very high temperature region, but the temperature drops rapidly
due to heat dissipation. They determined that beyond a specific limit, the energy of the spark
affects only the initial flame kernel radius, and not the temperature. Sher et al [5-8] applied the
proposed model in [4] to study the formation of actual methane-air flames and the effect of
variables on the initial flame kernel. They concluded that the spark kernel is grown in two steps.
The first, shorter stage consists of a pressure wave emission. This is followed by a longer period,
in which diffusion occurs. Initial flame kernel is formed during the second stage in a constant
pressure process. They could estimate the burning speed of methane-air flames in early stages
[8]. However, the estimation of initial conditions in early stages and other parameters such as
initial temperature of the kernel, radiation from hot gas, heat conductivity, and transport
properties is challenging. Ko et al [9, 10] theoretically and experimentally studied the spark
ignition of propane-air mixtures. They indicated the existence of a critical radius which depends
strongly on equivalence ratio. They also showed the importance of spark electrode gap, spark
modes (breakdown, arc, and glow), and cathode-anode falls on ignition process. Chen and Ju
[11] studied the evolution of the ignition kernel to a flame ball and they concluded that radiation
plays a very important role in transition of initial flame kernel to the actual self-sustained flame.
There are also numerous works which deal with the effect of geometry and type of spark
electrodes on kernel characteristics and flame propagation [12-21]. Most of these papers
illustrate the importance of energy losses in early stages, minimum initial radius, ignition energy
modes and their effects on flame formation.
The purpose of the present paper is to present a quantitative model for the intervening second
and third stages of process which study the electrical energy input to plasma, flame kernel
formation, and measuring the laminar burning speed.
5.2. Experimental System
Figure 1a shows the overall experimental system. Experiments were conducted in a
cylindrical combustion chamber with an inner diameter and length of 133.35 mm. Figure 1b
80
shows the cylindrical vessel. The combustible mixture was spark-ignited at the center of the
chamber using two spark plugs with extended electrodes. Two different sets of electrodes were
used to study the effect of electrode geometry on heat loss. They had diameters of 2.54 mm and
0.381 mm. Both of electrodes were of stainless steel. Both sets had a free length of 40 mm and
the spark gap was 1.0 mm. Two extended spark electrodes, shown in Figure 1b, initiate the
combustion process from the center.
Ignition system: An electronic ignition system consists of high voltage capacitor discharge
controlled by the data acquisition program which provides a spark with the necessary energy.
Ignition system has been designed with variable voltages and capacitors to produce ignition with
different energies. Voltage and current across the spark plug gap during the electrical discharge
have been measured by a voltage divider.
Optical system: a Z-type Shadowgraph ensemble has been set up to visualize the flame
propagation. A high speed CMOS camera (HG-LE, Redlake Inc.) with a capture rate of up to
40,000 frames per second is placed at the focal point of the second mirror. The capture rate and
shutter speed of the camera were optimized depending on the burning speed of the mixture and
the brightness of the flame. The light source for the optical system is a 10-Watt Halogen lamp
with a condensing lens and a pinhole of 0.3 mm in diameter, which provides a sharp and intense
illumination throughout the whole system. Additional information about the optical set up can be
found in previous works [22-24].
5.3. Experimental Results
5.3.1. Discharge Energy Measurements
Figure 2 shows the measured voltages and currents as a function of time for a spark plug in air
for maximum and minimum discharge energies (DE). The spike which is seen approximately at
5-10 μs shows the breakdown stage preceding the spark discharge. In this stage the gap is
bridged by the avalanche of electrons flowing from cathode to anode. Breakdown energy
depends on the spike magnitude and duration of the spark. In our experiments the breakdown
energy is about 0.3-0.6 mJ. The oscillations seen starting around 1 ms are feedback through the
electrical system. Figure 2 also shows the current flow through the spark plug gap and it can be
seen that increasing the discharge energy (DE) increases the current flowing across the gap.
When the current passes a threshold (~0.3 A) a transition occurs from glow to arc which
decreases the voltage abruptly. This transition is caused by thermionic effects causing electron
81
emission from the high temperature cathode. In lower discharge energies, because of relatively
low current, there is no arc mode. The glow discharge voltage (normal voltage Vn) is
independent of the current. It is a function of wire material and the gas. For air with steel as the
electrode material, the value of Vn is 270 volts [2, 25 and 26]. Our experimental observations are
very close to these values, as shown in Figure 2.
Once current and voltage are known as a function of time one can easily calculate the
instantaneous discharge power (DP) from DP=VI. Consequently the discharge energy from the
spark jump is DE=∫VIdt. Figure 3 shows the instantaneous power across the spark plug gap. For
higher energies, there is a sudden drop and rise in the power which is due to the voltage drop in
arc-glow transition. It should be noted that discharge energy is larger than the electrical energy
converted to thermal energy in the gas because a portion of the discharge energy is dissipated by
conduction into the electrodes. It is very difficult to measure the amount of energy dissipated in
the plasma but, as will be shown in subsequent sections, a good estimation can be made based
the anode and cathode voltage drops measured by others.
5.3.2. Shadowgraphs of the Kernel
Figures 4 and 5 show high speed shadowgraphs of plasma kernels for pure-air and methane/air.
As can be seen in Figure 4, the kernel radii for pure-air and methane/air flames are almost
identical at early times. In this stage (0-2 ms), the amount of heat released by chemical reactions
is negligible [8]. Therefore, the volume and temperature of the kernel depends only on the
electrical energy dissipated in the plasma kernel.
Figure 5 also shows that about 4 ms after spark, the air kernel becomes stable but the
methane/air continues to grow into a self-sustained propagating flame. In this stage chemical
energy and transport processes are the drivers of flame.
5.3.3. Kernel Growth for Air
Figure 6 shows the measured air radii as a function of time for two different spark energies. It
can be seen that the kernel radii increase significantly with time independent of discharge energy
(DE) but the final values increase only slightly with increasing discharge energy (DE).
5.4. Thermodynamic Model
A thermodynamic model has been developed to describe the growth of the plasma kernel
82
subsequent to the breakdown phase. Figure 7 shows the sketch of the model.
The major assumptions are as following:
6- All calculations start after breakdown stage and it is assumed that the pressure is
constant.
7- Since the relaxation time scale of different energy modes (translational, rotational,
vibrational, electronic) compared to plasma expansion time are small (O~10-9 s), all
species are in local thermodynamic equilibrium at a single temperature [1, 4, and 5].
8- Since the thermal boundary layer is thin, it is assumed that the kernel is a constant-mass
system.
9- It is assumed that the kernel is approximately spherical.
10- Assumed energy losses are (i) radiation from the plasma to the surroundings, (ii) heat loss
associated with anode and cathode voltage drops, and (iii) conduction losses to the
thermal boundary layers around the electrodes.
The governing equations are energy balance, equation of state, and mass conservation. The
equation for energy balance is given by:
VpR
cQQ
dt
dDE
t
E pradcond
(1)
where E is the energy of the plasma kernel, dDE/dt is the electrical energy dissipation rate, Qcond
is the conduction energy loss to the thermal boundary layer, Qrad is the radiation energy loss, cp
is the heat capacity, R is the gas constant, p is the pressure, and V is the volume of kernel.
The equation of state is
pV =nRT (2)
where n is number of moles and T is the temperature. The total number of moles is determined
by:
z
iinn
1
(3)
where z is the number of species.
The mass conservation equation is
83
z
BBEB0
22
ε = 0, 1, 2, 3, …z
(4)
In this equation, EB is the elemental atom number of atom B, and ε is the charge of ions.
5.4.1. Thermodynamic Properties
the thermodynamic properties of air have been calculated by statistical thermodynamic methods.
These parameters, including cp and the enthalpy of the mixture, have been calculated in
temperature range of 300-100,000 K. More details about calculations can be found in [27]. For
air the considered species are N2, N, N+, N2+, N3+, N4+, N5+, N6+, O2, O, O+, O2+, O3+, O4+, O5+,
O6+, O7+, and e (electron). Figure 8 shows the number of species for an air plasma normalized by
the number of the elemental atoms in the system. It can be seen that the number of species
increases rapidly with temperature due to the large increase in the number of electrons at high
temperature. Figure 9 shows the heat capacity of air at high temperatures. The peaks in this curve
are associated with the energy required to dissociate and ionize the components of air and are
responsible for most of its heat capacity.
5.4.2. Electrical Energy
The calculations start after breakdown phase. A negligible portion of discharge energy is
consumed in breakdown phase. Equation (5) is the discharge energy balance:
SEQIVdtdtIVdtIVIVdtDE ca
bt
b col
t
b fall
b 00
)()( (5)
The first term is the energy associated with breakdown, second term is anode and cathode fall
energy ( caQ ) which is dissipated into the electrodes, and the last term is the electrical energy
dissipated within the plasma kernel (SE).
As previously discussed, the experimental data show that breakdown is a very short process
(O~10-6 s) and its net energy is a small fraction of total energy. After the breakdown phase, arc
or glow modes are established (based on the amount of current). In this stage a part of energy is
dissipated into the electrodes by conduction. We will show in subsequent sections that in
addition to conduction, radiation is an important source of energy losses.
84
5.4.3. Conduction to Electrodes by Thermal Boundary Layer
Conduction to electrodes was calculated using an unsteady conduction process in the boundary
layer. It can be shown that
dtt
TTAkQ eT
cond )(
2 0 (6)
In this equation kT is the thermal conductivity of the gas; Ae is the contact area of electrodes with
the gas, T0 is the temperature of the electrode, and is the thermal diffusivity.
5.4.4. Effect of Initial Temperature
Initial temperature of the kernel is important to the ionization process of the kernel. As
mentioned before, the calculations start after the emission of the shock wave. The initial
temperature of the kernel mainly depends on the breakdown energy and the initial volume of the
kernel. Figures 10 and 11 show the effect of initial temperature on kernel growth and
temperature. Figure 10 shows that lower initial temperatures result in larger kernel radii, because
for a constant volume initial kernel the number of particles is higher for lower initial
temperatures. Figure 11 demonstrates that initial temperature affects the temperature profile
dramatically. The appropriate range of initial temperature proposed by other researchers is about
6000-7000 K [1, 2, 4-6].
5.4.5. Effect of Initial Radius
Figures 12 and 13 show the effects of initial radius on flame kernel growth and temperature.
Initial radius does not have a big influence on the growth rate of the kernel but it has a
remarkable effect on the temperature of the kernel. Increasing the initial radii just by 0.05 mm
increases the final temperature by about 10,000 K.
5.4.6. Best Fit to the Model
The inputs of the model are initial radius, initial temperature, and the spark energy. The initial
radius is measured in the experiments by a high resolution camera. The initial temperature of the
plasma for air depends on breakdown energy. However, the agreed range among researchers for
a wide range of breakdown energies is 6000-7000 K. Table 1 shows the values of initial
conditions.
85
Figure 14 shows the comparison between the model and experiment for air. This figure also
shows the effect of radiation on predictions of the model. The correlations of air radiation are
taken from Schreiber et al [28] who collected data for transport properties of air at high
temperatures in optically thin conditions. Experimental data presented in Figure 14 show a
decline in the radii of kernel after a peak which depends on spark power and duration. Figure 14
shows that in zero radiation condition the radius remains constant after the peak. But the addition
of the radiation term in equations predicts a decline in radii which is observed in experiments as
well. The importance of radiation strongly depends on the temperature. Figure 14b demonstrates
that at higher discharge energy, the effect of radiation becomes more important which is due to
larger area of the kernel and higher temperature of the plasma. By including radiation term, the
predictions show good agreement with experiment. Major terms which control the growth of the
kernel are heat capacity, cathode falls and radiation losses.
5.4.8. Fraction of Total Energy Losses
Figure 15 shows different energy terms in air kernels. It can be seen that in air plasma, radiation
can dissipate 20-60% of discharge energy (DE) depending on spark duration and temperature.
This percentage strongly depends on the current and the temperature of the arc [29]. 25-30% of
the discharge energy is dissipated by the cathode fall conduction and thermal boundary layer
dissipations. A small portion of the discharge energy is dissipated by thermal boundary layer
around the electrodes. By this token, just about 10-25% of discharge energy is converted to the
thermal energy. Although Teets and Sell [30] state that the major part of energy dissipation is
due to conduction losses to the electrodes the results are in agreement with net results of Teets
and Sell [30] and Maly et al [1-2]. Table 2 shows the summary of energy dissipations in air.
5.5. Methane/Air Mixture
5.5.1. Flame Radius
In this section the growth of methane/air flames will be discussed. The experiments have been
done with various equivalence ratios from 0.7-1.4. The discharge energies were 24 and 81 mJ
and two electrodes were used whose specifications were explained in previous sections. Figure
16 shows the flame radii of the mixtures at stoichiometric condition, low and high variant spark
energies, and two different spark electrodes. It is shown that spark electrode geometry does not
affect the flame speed. Figures 16b show the effect of spark energy on flame propagation. These
86
figures demonstrate that energy of spark affects the location of flame, but asymptotic flame
growth rate is independent.
5.5.2. Model Equations
Figure 17 is the sketch of the model. It is assumed that the flame is spherical and propagates in a
constant pressure process. The mass is added to the burned gas region by burning the unburned
gas. The mass conservation equation on the flame front is:
)]/exp(1[ cuub tASmt
m
(7)
where m is the mass of the burned gas zone, bm is the mass burning rate, u is the density of
unburned gas, A is the flame area, Su is the laminar burning speed, and c is a characteristic time
scale. As it will be shown in experimental data the flame speed tends to an asymptotic value after
a specific time scale which depends on chemical and thermodynamic properties of the mixture.
The exponential term and the corresponding time scale c in equation (7) represent this
behavior.
The energy balance is given by:
VpQQdt
dSEhTcm
t
Eradconduupub
)( (8)
)( bbbv hTcmE (9)
where, E is the energy of the burned gas region, h is the enthalpy and cvb is the heat capacity
at constant volume. dt
dSEis the rate of spark energy variations inside the plasma.
The equation of state is:
uuubbb TRTRp (10)
where is the density.
Equation (8) can be written as
87
radcondbpbbb
pb
b
pb QQdt
dSETcmrpA
R
cVp
R
c
t
)( (11)
Let:
))/exp(1( cub
u
uuu
bbbbbbc tS
ATR
TRm
pA
TRmr
(12)
pAdt
dSE
c
Rr
pelec
1 (13)
pA
Q
c
Rr cond
pcond
(14)
pA
Q
c
Rr rad
prad
(15)
In equations 11-15, A is the area of the flame and r is the radius of the flame. By dividing
Equation (11) by pAR
c
b
pb , we will have:
radcondelecc rrrrr (16)
In this equation the role of each energy term on flame speed has been involved. In equation (16),
cr is the flame speed term corresponding to chemical energy, elecr is the flame speed term
corresponding to electrical energy, and condr and radr are the effects of conduction and radiation
energy losses on flame speed. Having experimental data on the radius of flame and electrical
energy, the experimental data were fitted by equation (16). The achieved parameters after fitting
are uS and c . Figure 18 shows the flame speed values measured by experiments and fitted by
the model. The symbols represent the experimental data. The fluctuations in early stages are
associated with the oscillations of heat capacity in early stages which affects the dynamics of the
kernel. Later on, the oscillations are due to acoustic waves. In Figure 18 the effect of other terms
presented in equation (16) is also shown. High flame speed values in the beginning are due to
very high temperature plasma gas. In almost all cases radiation plays an important role in early
stages due to the emission of high temperature gas. Figure 18 indicates that chemical energy term
has an exponential behavior and it takes time to become asymptotic. Experimental data from
88
Dreizler et al [31] show that deposition of chemical energy in the kernel begins in the early
stages of flame formation but in the first 2 ms the energy supply is dominated by electrical
energy. The amount of energy supplied by electrical energy is almost three orders of magnitude
higher than the chemical energy. After 2 ms the electrical energy is eliminated and the chemical
energy becomes the driver of the flame. Based on conditions, laminar flame becomes asymptotic
ultimately. In early stages of ignition the flame speed is more dominated by expansion of the
plasma kernel which is a constant pressure and mass process. The experimental data verify this
theory as well. Figure 5 shows that in early stages the radii of air and methane/air mixture do not
differ dramatically. The transition process from constant mass expansion to the actual self-
sustained flame is a complicated process and it depends on the properties of the mixture, energy
loss processes, mass and heat diffusion and the rate of chemical reactions. However, the
chemical energy time scale c can quantitatively show the transition duration. Table 3 shows the
values of uS and c at two different spark energies and spark electrodes. It is shown that the
laminar burning speed is almost independent of spark energy and electrode geometry. The slight
difference in results can be attributed to experimental errors.
5.6. Errors and Uncertainties
The sources of experimental uncertainty can be errors in preparation and filling the vessel by
methane/air mixture, different discharge energies, and software errors in measuring the radii. Our
analyses in previous publications prove that errors due to mixture stoichiometry are ~ 1% [22-
24]. The data have been collected with high resolution and high frame per second to minimize
the errors of radii measurement which is ~ 0.5%. Each experiment was performed at least three
times at each operational condition. According to statistical methods, three identical runs are
sufficient in order to ensure that the confidence level of the experiment is above 95% [32]. By
this procedure and considering the human errors, the experimental uncertainties are minimized to
less that 5%. The errors in calculations can be due to laminar burning speed fittings and taking
derivative of radii data vs time. However, these errors never exceed 1%.
5.7. Comparison with Other Experimental Data
The laminar burning speeds of methane/air flames have been measured by several researchers.
The experimental and theoretical data shown in Figure 19 have been obtained by different
experimental methods. Figure 19 shows the comparison of present results with other
89
experimental and theoretical data. Our measurements are in good agreement with other data.
However, the discrepancy among the data can be associated with experimental errors and
different techniques used for measurements. These discrepancies increase in the vicinity of
ignition limits at lean and rich conditions (0.7 and 1.3).
Acknowledgement
This research has been done by the support of Office of Naval Research (ONR), Grant No.
N00010-09-1-0479. The authors are thankful for technical monitoring of Dr. Gabriel Roy.
References
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90
55-77.
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[17] T. Berglind and J. Sunner . Combust. Flame 63 (1986) 279-288.
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[19] S.V. Arpacı, Y. Ko, M. Taeck Lim, H.S. Lee. Combust. Flame. 135 (2003) 315-322.
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[23] K. Eisazadeh-Far, F. Parsinejad and H. Metghalchi, Fuel 89 (2010) 1041–1049.
[24] K. Eisazadeh-Far, A. Moghaddas, J. Al-Mulki, H. Metghalchi. Laminar Burning Speeds of
Ethanol/Air/Diluent Mixtures. Accepted in 33rd Symposium (International) on Combustion.
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(Springer, Berlin 1934)
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91
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(a)
(b)
Figure 1: (a): the experimental set up of the system, (b): cylindrical vessel
92
Time (ms)
Vo
ltag
e(V
)
0 1 2 30
100
200
300
400
500
600
700
800
900
1000
1100
1200
1300
DE: 24 mJ DE: 81 mJ
arc mode glow mode
Breakdown mode : 0.6 mJ
Time (ms)
Cu
rre
nt
(A)
0 1 2 30
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
0.45
0.5
DE: 24 mJ
DE: 81 mJ
Figure 2: Voltage and current versus time for high and low energy: Air
(Arc to glow transition is seen in high energy case)
93
Time (ms)
Po
we
r(W
)
0 1 2 30
10
20
30
40
50
60
70
80
90
100
110
120
DE : 24 mJDE : 81 mJ
Figure 3: Spark discharge power of air at low and high energies
94
Air methane/air
12.5
mm
12.5
mm
t= 0.1 ms
t = 0.5 ms
t = 1 ms
Figure 4: snapshots of air and methane/air kernels, P=1 atm, T=300 K,
discharge energy (DE) = 24 mJ. (different contrast values of images cause the electrodes
appear in different thicknesses)
95
Air methane/air
t=0.5ms
30 mm
30 mm
t=2 ms
t=4 ms
Figure 5: Snapshots of air and stoichiometric methane/air flame, P=1 atm, T=300 K,
Spark discharge energy (DE) = 24 mJ
96
+
+
+
++
++
++
++
+++++++++
++++++++++++
+++ + + + +
Time (ms)
r(m
m)
0 0.5 1 1.5 20
0.5
1
1.5
2
2.5
air, DE = 24 mJ
air, DE = 81 mJ
Figure 6: air radii at two different spark energies, P = 1 atm, T = 300 K
97
Figure 7: the sketch of the model
98
T (K)
No
rma
lize
dp
art
icle
nu
mb
ers
25000 50000 75000 1000000
3
6
9
12
Figure 8: particle numbers of air normalized by elemental atom numbers vs temperature
99
Temperature (K)
c p(k
J/kg
.K)
0 25000 50000 75000 1000000
10
20
30
40
50
Figure 9: Heat capacity of air versus temperature
100
Time (ms)
r(m
m)
0 0.5 1 1.5 2 2.5 30
0.5
1
1.5
2
2.5
Ti = 3000 KTi = 7000 KTi = 10000 K
Figure 10: the effect of initial temperature on air plasma growth,
discharge energy = 24 mJ, ri=0.5 mm
101
Time (ms)
Te
mp
era
ture
(K)
0.5 1 1.5 2 2.5 30
10000
20000
30000
40000
50000
60000
70000
Ti = 3000 KTi = 7000 KTi = 10000 K
Figure 11: the effect of initial temperature on air plasma temperature profile,
discharge energy = 24 mJ, ri = 0.5 mm
102
Time (ms)
r(m
m)
0 0.5 1 1.5 2 2.5 30
0.5
1
1.5
2
2.5
ri = 0.45 mmri = 0.5 mmri = 0.55 mm
Figure 12: the effect of initial radius on air kernel growth temperature,
Ti = 7000 K, discharge energy = 24 mJ
103
Time (ms)
Te
mp
era
ture
(K)
0 0.5 1 1.5 2 2.5 30
10000
20000
30000
40000
50000
60000
70000
ri = 0.45 mmri = 0.5 mmri = 0.55 mm
Figure 13: the effect of initial radius on air kernel temperature,
Ti = 7000 K, discharge energy = 24 mJ
104
Time (ms)
r(m
m)
0 0.5 1 1.5 2 2.5 30
0.5
1
1.5
2
2.5
3
zero radiationwith radiationExperiment
DE = 24 mJ
Ti = 7000 K
ri = 0.5 mm
Qrad = 14 % of DE
de = 0.381 mm
(a)
Time (ms)
r(m
m)
0 0.5 1 1.5 2 2.5 30
0.5
1
1.5
2
2.5
3
3.5
zero radiationwith radiationExperiment
DE = 81 mJ
Ti = 7000 K
ri = 0.65 mm
Qrad = 62% of DE
de = 0.381 mm
(b)
Figure 14: predictions of air plasma radii and the comparison with experiments in a: low and b:
high discharge energies, P = 1 atm, T= 300 K, Symbols: experiment, Solid line: model
105
Time (ms)
rate
of
en
erg
y(W
)
0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 50
10
20
30
40
50
60
70
80
DEQca
Qrad
Qcond
DE = 81 mJ
DE = 24 mJ
Figure 15: rate of variations of discharge energy (DE), cathode-anode fall dissipations ( caQ ),
radiation losses ( radQ ), and conduction dissipations by thermal boundary layer ( condQ ) for air, ri
= 0.5 mm, de = 0.38 mm
106
Time (ms)
r(m
m)
0 2 4 6 8 10 12 14 160
5
10
15
20
25
30
35 de = 0.381 mmde = 2.54 mm
DE = 24 mJ
= 1
Time (ms)
r(m
m)
0 2 4 6 8 10 12 14 160
5
10
15
20
25
30
35 de = 0.381 mmde = 2.54 mm
DE = 81 mJ
= 1
(a)
Time (ms)
r(m
m)
0 2 4 6 8 10 12 14 160
5
10
15
20
25
30
35 DE = 81 mJDE = 24 mJ
de = 0.38 mm
= 1
Time (ms)
r(m
m)
0 2 4 6 8 10 12 14 160
5
10
15
20
25
30
35 DE = 81 mJDE = 24 mJ
de = 2.54 mm
= 1
(b)
Figure 16: flame radii of methane/air mixtures at two different spark energies and electrodes, P =
1 atm, T = 300 K, 1 , a: effect of discharge energy, b: effect of electrode geometry
107
Figure 17: schematic of flame propagation model
108
Time (ms)
r.(m
/s)
0 2 4 6 8 100
1
2
3
4
5
6
ExperimentElectrical energyChemical energyConduction energy lossradiation energy lossFit
= 1
de = 0.381 mm
DE = 24mJ
Time (ms)
r.(m
/s)
0 2 4 6 8 100
1
2
3
4
5
6
ExperimentElectrical energyChemical energyConduction energy lossradiation energy lossFit
= 1
de = 0.381 mm
DE = 81 mJ
Time (ms)
r.(m
/s)
0 2 4 6 8 100
1
2
3
4
5
6
ExperimentElectrical energyChemical energyConduction energy lossesradiation energy lossFit
= 1
de=2.54 mm
DE = 24 mJ
Time (ms)
r.(m
/s)
0 2 4 6 8 100
1
2
3
4
5
6
ExperimentElectrical energyChemical energyConduction energy lossradiation energy lossFit
= 1
de = 2.54 mm
DE = 81 mJ
Figure 18: flame speeds of methane/air mixtures and the effect of other terms,
P = 1 atm, T = 300 K, 1
109
-
-
-
- --
-
+
+
+ ++
+
+
Su
(cm
/s)
0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 1.40
6
12
18
24
30
36
42
Tahtouh et al [33]Gu et al [34]Bradley et al [35]Hassan et al [36]Halter et al [37]Coppens et al [38]present study
-
+
Figure 19: laminar burning speeds vs equivalence ratio and comparison with other experimental
data, P = 1 atm, T = 300 K
110
Table 1: initial conditions for calculations
Air (DE =24 mJ) Air (DE = 81 mJ)
Initial radius (mm) 0.5 0.65
Initial temperature (K) 7000 7000
DE (mJ) 24 81
SE (mJ) 18 60
Table 2: Summary of fractional energy terms
Air (DE = 24 mJ) Air (DE = 81 mJ)
cathode-anode fall losses 26.60% 26%
thermal boundary layer conduction 0.40% 1%
radiation losses 48% 62%
converted to thermal energy (present study) 25% 11%
converted to thermal energy (Teets and Sell [30]) 24% 14%
converted to thermal energy (Maly and Vogel [1]) 30%
111
Table 3: summary of results
DE = 24 mJ DE = 81 mJ DE = 24 mJ DE = 81 mJ DE = 24 mJ DE =81 mJ
= 0.8 = 0.8 = 1 = 1 = 1.2 = 1.2
Su (cm/s)
0.4 mm 22 23 35.7 36 33.1 32.8
2.5 mm 24.2 23.5 35.6 34.8 32.8 32.2
τ c (ms)
de = 0.38 mm 1 1.5 1.4 1.5 4.24 2.5
de = 2.54 mm 2.8 2 1.4 1.02 5 1.07
112
6. A Thermodynamic Model to Calculate Burning Speed of Methane-Air- Diluent Mixtures
International Journal of Thermodynamics, Vol. 11(No.4)
pp.151-160, 2008.
113
6. A Thermodynamic Model to Calculate Burning
Speed of Methane-Air- Diluent Mixtures
Faranak Rahim, Kian Eisazadeh-Far, Farzan Parsinejad, and Hameed Metghalchi*
Mechanical and Industrial Engineering Department, Northeastern University,
Boston, Massachusetts 02115
USA
* Corresponding Author:
Mechanical, Industrial and Manufacturing Engineering
334 Snell Engineering Center, Northeastern University
360 Huntington Avenue, Boston, MA 02115, USA
Tel: (617) 373-2973
Fax: (617) 373-2921
E-mail: [email protected]
114
Abstract
The burning speeds and flame structure of methane-air-diluent mixtures over a wide
range of pressures and temperatures have been studied using both a constant volume spherical
chamber and a cylindrical chamber with end windows. The effect of automotive exhaust gas on
the burning speeds was measured using a mixture of 86 % N2 and 14 % CO2 as the diluent. A
thermodynamic model was developed to calculate the mass fraction burned and the burning
speeds from the measured dynamic pressure rise in the chamber. The model assumes a central
burned gas core of variable temperature surrounded by an unburned gas shell of uniform
temperature. Heat losses due to radiation from the burned gas and conduction to the wall and
electrodes are included. The effect of the temperature rise in the preheat zone at the flame front is
also included. Photographic observations were made through the end windows in the cylindrical
chamber using a high-speed charged coupled device (CCD) camera with variable speed of up to
8000 frames/second. Smooth, cracked and cellular flame were all observed and the regions
where they occurred have been roughly determined. The measured values of burning speeds have
been compared with laminar burning speeds calculated using the PREMIX flame speed code and
the GRI-Mech 3.0 mechanism. This model is valid for high temperatures and low pressures and
agrees well with the measurement under these conditions when the flames are smooth or cracked
and lean or stoichiometric. For cellular flames at high pressures and low diluent fraction, the
measured burning speeds are higher than the PREMIX values. For rich mixtures, all the flames
observed were smooth but the measured burning speeds were lower than the PREMIX values.
Possible reasons for this are discussed.
115
NOMENCLATURE
A = area
E = energy
cp = constant pressure specific heat
cv = constant volume specific heat
e = specific energy
hf = specific enthalpy of formation
m = mass
p = pressure
Q = heat loss
r = radius
R = specific gas constant
Sb = mass burning speed
Sf = flame speed
t = time
T = temperature
ug = gas speed
V = volume
Vc = combustion chamber volume
v = specific volume
x = mass fraction
y = dimensionless time
yb = burned gas volume fraction
z = dimensionless pressure
Greek
= thermal diffusivity
p = Planck mean absorption coefficient
= boundary displacement thickness
= ratio of constant pressure and constant volume specific heats
= radial distance from electrode
= density
116
= Stefan-Boltzman constant
= characteristic burning time
Subscripts
b = burned gas
e = electrode
i = initial conditions
r = radiation
u = unburned gas
w = wall
eb = electrode boundary layer
wb = wall boundary layer
ph = preheat zone
bs = isentropically compressed burned gas
us = isentropically compressed unburned gas
6.1. Introduction
The purpose of this paper is to provide experimental data on the mass burning rates,
burning speed, and flame structure that are important both for developing and testing fluid
dynamic and chemical kinetic models of hydrocarbon oxidation and for a wide range of direct
practical applications in the fields of engines, burners, explosions, and chemical processors.
Over the past several decades, a great deal of experimental [1, 2] and theoretical [3, 4]
work has been done on the measurement and kinetic modeling of laminar burning speeds. This
has led to the development of fairly complete and reliable flame speed codes and chemical
kinetic models for predicting the laminar burning speeds of simple hydrocarbon mixtures at high
temperatures and low pressures. However, relatively little effort has been devoted to measuring
or developing models of laminar burning speeds at low temperatures and high pressures.
Experimental and theoretical studies of ignition delays in constant volume chambers [5] and
rapid compression machines [6] clearly demonstrate the importance of alkyl peroxides under
these conditions. Since these have been omitted from most current models, users are explicitly
advised that they are invalid at low temperatures and high pressures [7]. This is especially
unfortunate because of the large number of practical applications involving low temperature/high
pressure flames.
117
The methods used to measure burning rates and flames speeds can be characterized as
either constant pressure [8-25] or constant volume [26-42]. Constant pressure methods, such as
those employing flat flame burners, are limited to a relatively narrow range of temperatures and
are most useful for obtaining data at atmospheric pressure. The principal disadvantages of the
constant pressure methods are that they require significant corrections for flame geometry and
conductive heat loss to the burner. Recently an effort has been made to measure the heat loss to
the burner [43] and calculate the adiabatic burning speed, but this could only be done at
atmospheric pressure and room temperature.
Constant volume methods, such as those employing spherical combustion chambers,
cover a much wider range of temperatures and pressures and provide a range of data along an
isentrope in a single experimental run. In addition, corrections for flame geometry or heat loss
are generally quite small. Spherical chambers have been used by a number of investigators [36-
38, 44] to measure burning speeds for a wide range of fuels, equivalence ratios, diluent
concentrations, pressures and temperatures. Flame instabilities such as cracking, wrinkling and
buoyant rise have been observed by many researchers [44-48] and have subtle effects [44].
In the current study, burning rates and flame speeds have been measured for methane-air-
diluent (86 % N2 and 14 % CO2 ) mixtures for equivalence ratios of 0.8, 1.0 and1.2 over the
pressure range 1-50 atm and unburned gas temperature range 298-500 K. The pressure rise due
to combustion in a constant volume spherical chamber was recorded and a thermodynamic
analysis of the pressure time record was used to calculate the burning rates and flame speeds.
The flame structure was investigated using a cylindrical chamber with end windows. Buoyancy
and instabilities in the flame structure were observed in this vessel. The measured values of the
burning speeds have been compared to calculations made using the PREMIX flame speed code
[49] with GRI-Mech 3.0 mechanism [7]. As expected, the agreement is good for high-
temperature, low-pressure conditions. However for low temperature, high pressure conditions,
the calculated burning speeds are significantly higher than the measured values.
6.2. Experimental Facilities
The burning speed measurements were made in both a spherical and a cylindrical
combustion chamber [50-53]. The spherical chamber consists of two hemispheric heads bolted
together to make a 15.4 cm inner diameter sphere. The chamber was designed to withstand
pressures up to 425 atm and is fitted with ports for spark electrodes, diagnostic probes, and for
filling and evacuating it. A thermocouple inserted through one of the chamber ports was used to
118
check the initial temperature of the gas inside the chamber. A Kistler 603B1 piezo-electric
pressure transducer with a Kistler 5010B charge amplifier was used to obtain dynamic pressure
vs. time records from which the burning rate was determined. Ionization probes mounted flush
with the wall at the top and bottom of the chambers were used to measure the arrival time of the
flame at the wall and check for spherical symmetry and buoyant rise.
The companion cylindrical chamber has a diameter and length equal to 13.3 cm, which
makes its volume equal to that of the spherical chamber. This chamber was designed to operate
over the same pressure and temperature range as the spherical chamber and is equipped with
similar access ports. The primary purpose of this facility is to permit optical observation of the
flame shape and structure under conditions as close as possible to those in the spherical chamber
and the initial pressure rise and flame development are identical in both chambers. A high speed
CCD digital video camera is used to obtain shadowgraphs of the flame at speeds up to 8000
frames/second.
The gas handling system consists of a vacuum pump for evacuating the system and a
valve manifold connected to gas cylinders for preparation of the fuel/air/diluent mixtures. Partial
pressures of the fuel mixtures were measured using Kulite strain gauge pressure transducers in
the 0-15 atm range. Two spark plugs with extended 2 mm diameter electrodes were used to
ignite the mixture at the center of the chambers. An electronic ignition system controlled by the
data acquisition program provides the spark.
The data acquisition system consists of a Data Translations 16 bit data acquisition card,
which records the pressure change during combustion at a rate of 250 kHz. The analog to digital
converter card receives the pressure signal from the charge amplifier and the signals from the
ionization probes. All signals are recorded by a personal computer and an output data file is
automatically generated. The output data file contains information about the partial pressures and
initial temperature of all the gases used: fuel, oxygen and diluent. An oscilloscope is used to
monitor the ignition signal and the outputs of the ionization probes and the pressure transducer in
real time to insure that the various sensors are working and that the system has fired properly.
After the chamber is filled with the proper mixture, several minutes are allowed before
the mixture is ignited. This is sufficient to permit any turbulence inside the vessel to decay. At
least three runs at each initial condition were made to provide a good statistical sample. Based on
a statistical analysis, it was found that three runs are enough to achieve a 95% confidence level.
119
6.3. Theoretical Model
The theoretical model used to calculate the burning speed from the pressure rise is based
on one previously developed by Metghalchi and Keck [36-38] modified to include the effects of
temperature gradients in the burned gas and flame preheat zone. It is assumed that gases in the
combustion chamber can be divided into burned and unburned regions separated by a reaction
layer of zero thickness as shown schematically in Figure 1. It is further assumed that: the burned
and unburned gases are ideal, the burned gas is in chemical equilibrium, the unburned gas
composition is frozen, the pressure throughout the chamber is uniform, compression of both
burned and unburned gases is isentropic, and the heat flux due to the temperature gradient in the
burned gas is negligible. For the conditions of interest in the present work, all these assumptions
have been validated by numerous experiments in constant volume chambers and internal
combustion engines carried out over the past several decades.
6.3.1. Burned Gas Mass Fraction and Temperature
For spherical flames, the temperature distribution of the gases in the combustion chamber
and the burned gas mass fraction can be determined from the measured pressure using the
equations for conservation of volume and energy together with the ideal gas equation of state
pv = RT (1)
where p is the pressure, v is the specific volume, R is the specific gas constant and T is the
temperature.
The mass conservation equation is
m=mb+mu=pi(Vc-Ve)RTi (2)
where m is the mass of gas in the combustion chamber, mb is the burned gas mass, mu is the
unburned gas mass, Vc is the volume of the combustion chamber, Ve is the electrode volume, and
the subscript i denotes initial conditions.
The total volume of the gas in the combustion chamber is
Vc - Ve = Vb + Vu (3)
where
bb m
ebbs
m
b VdmvvdmV00
(4)
120
Vb is the volume of the burned gas, vbs is the specific volume of isentropically compressed
burned gas,
dmvvVbm
bseb )(0
(5)
Veb is the displacement volume of the electrode boundary layers,
(1 )b
m
u b us wb ph
m
V vdm m x v V V (6)
Vu is the volume of the unburned gas, xb=mb/m is the burned gas mass fraction, vub is the specific
volume of isentropically compressed unburned gas,
dmvvVwb
uswb )( (7)
Vwb is the displacement volume of the wall boundary layer,
dmvvVph
usph )( (8)
Vph is the displacement volume of the preheat zone ahead of the reaction layer.
The energy conservation equation is
E - Qw - Qe - Qr = Eb + Eu (9)
where E is the initial energy of the unburned gas, Qw is the conduction heat loss to the wall, Qe is
the conduction heat loss to the electrodes, Qr is the heat loss due to radiation from the burned
gas,
eb
m
bs
m
b EdmeedmEbb
00
(10)
Eb is the energy of the burned gas, ebs is the specific energy of isentropically compressed burned
gas,
bm
bseb dmeeE0
)( (11)
121
Eeb is the energy defect of the electrode boundary layer,
phwbusb
m
m
u EEexmedmEb
)1( (12)
Eu is the energy of the unburned gas, eus is the specific energy of isentropically compressed
unburned gas,
wb
uswb dmeeE )( (13)
Ewb is the energy defect of the wall boundary,
ph
usph dmeeE )( (14)
Eph is the energy defect of the preheat layer.
Using the perfect gas relation
e-hf = pv/(-1) (15)
where hf is the specific enthalpy of formation of the gas at zero degrees Kelvin and =cp/cv is the
ratio of the constant pressure and constant volume specific heats, and assuming constant specific
heats for the gases in the boundary layers and the preheat zone, the integrals in Eqs. 11, 13 and
14 may be evaluated approximately to give
)1/()1/()( bebb
eb
bseb pVdmvvpE (16)
)1/()1/()( uwbu
wb
uswb pVdmvvpE (17)
)1/()1/()( uphu
ph
usph pVdmvvpE (18)
A relationship between the wall heat transfer and the displacement volume for a gas subject to a
time dependent pressure has been derived by Keck [54]. In the case of rapidly increasing
pressure such as that occurring during constant volume combustion, the terms representing
compression work on the boundary layer may be neglected and resulting equations are
122
Qe = pVeb/(b-1) = Eeb (19)
Qw = pVwb/(u-1) = Ewb (20)
in which we have used Eqs. 16 and 17. Note that, to this approximation, the heat loss to the wall
exactly equals the energy defect in the boundary layer. Substituting the relation dm=dV into
Eqs.5, 7 and 8 we obtain
Veb=2rerbeb (21)
Vwb=4rc2wb (22)
Vph=4rb2ph (23)
where re is the radius of the electrodes, rb is the radius of the burned gas, rc is the radius of the
combustion chamber,
br
0 0 bbseb rdrd1r /)/),(( (24)
eb is the displacement thickness of the electrode boundary layer in which is the radial distance
from the electrode,
drrwb
uswb )1/)(( (25)
wb is the displacement thickness of the wall boundary layer, and
drrph
usph )1/)(( (26)
ph is the displacement thickness of the preheat zone. Using the approximation
)1/()/)(()1/),(( 2/1 wbbb
eb
bbs TTrrrdr (27)
Eq. 24 can be integrated over r to give
)1/()/)(3/2( 2/1 wbbbbeb TTrr (28)
where b is the thermal diffusivity of the burned gas, Tw is the wall temperature, and Tb is the
burned gas temperature.
The wall boundary layer displacement thickness can be calculated using the expression
123
derived by Keck [54]
zdzdzzzzz z
z
uwb
0
2/1/1/12/1 ))(()(
(29)
where u is the thermal diffusivity of the unburned gas, is a characteristic burning time, y=t/ is
the dimensionless time, and z=p/pi is the dimensionless pressure. For combustion in closed
chambers, the dimensionless pressure can be approximated by
z=1+y3 (30)
Substituting this expression in Eq. 29 we obtain
1/ 2 1/ 2 (1 1/ )/ / / 1u
wb u i it p p p p (31)
The displacement thickness of the preheat zone has been evaluated assuming an
exponential temperature profile
)(/)/)(exp()1/(1/ rrrrTTTT usbbuubu (32)
Substituting Eq. 32 into Eq. 26 we obtain
ph
bubbubph drrrrrrTT 211 )/()1)/)exp()1/(( (33)
bu rr / , Eq. 33 can be integrated approximately to give
)/ln()1/)(/( ububbuph TTTTr (34)
Note that the displacement thickness of the preheat zone is negative while those of the thermal
boundary layers are positive.
The radiation heat loss from the burned gas was calculated using
t
rr dtQQ0
' (35)
where
4bbpr TVQ (36)
is the radiation rate, p is the Planck mean absorption coefficient and is the Stefan- Boltzman
124
constant [55].
Finally combining Eqs. 3, 4 and 6 gives
bx
phwbebusiusbs mVVVvvdxvv0
/)()( (37)
and combining Eqs. 9, 10, 12 and 18-20 gives
bx
ruphusiusbs mQpVeedxee0
/))1/(()( (38)
where vi=(Vc-Ve)/m and ei=Ei/m are the initial specific volume and energy of the unburned gas in
the chamber.
Equations 37 and 38 contain the three unknowns p, xb(p), and Tb(xb). Given pressure, p(t),
as a function of time, they can be solved numerically using the method of shells to obtain the
burned mass fraction, xb(t), as a function of time and the radial temperature distribution T(r,t).
The mass burning rate, bb xmm , can be obtained by numerical differentiation of xb(t). The
thermodynamic properties of the burned and unburned used in the calculations were obtained
from the JANAF Tables [56].
If the specific heats of the burned and unburned gases are assumed constant, Eq. 15 can
be used to evaluate the integral in Eq. 38 and we obtain
p(vbs/(b-1)-vus/(u-1))=hub+p(vi-vus)/(u-1)+(pVph/(u-1)-Qr)/m (39)
where hub=hfu-hfb is the difference between the enthalpies of formation of the unburned and
burned gas at zero degrees Kelvin. Equations 37 and 39 are identical to those previously derived
by Metgalchi and Keck [37, 38] with correction for radiation heat loss, conduction heat loss to
the electrodes, and the displacement thickness of the preheat zone added. Given the pressure,
they can be solved analytically to obtain an excellent approximation for xb and (RT)bs=pvbs.
However, they do not give the temperature distribution in the burned gas. It is of interest to note
that if the small correction terms for the preheat zone and the heat loss to the electrode are
neglected, xb and (RT)bs=pvbs depend only on the pressure and are independent of the flame
shape.
125
6.3.2. Burning Speed, Flame Speed and Gas Speed
For closed flames, the burning speed may be defined
bubb AmS / (40)
where Ab is the area of a sphere having a volume equal to that of the burned gas. This expression
is valid for smooth, cracked, or wrinkled flames of any shape. For smooth spherical flames
bbbbbb rAVm (41)
where b is the average value of the burned gas density.
Differentiating the mass balance equation
mb = m-uVu=(u/b)b(Vc - Ve -Vb) (42)
with respect to time and neglecting the small contribution from the derivative of u/b, we obtain
)))((/( bbbbbecbub rAVVVm (43)
where
Ab=4rb2-2re
2 (44)
is area of the reaction zone, re is the electrode radius and rb is given by the equation
Vb = (4/3)rb3-2re
2rb (45)
Using Eq. 41 to eliminate b in Eq. 43, gives
))1/(/( bubbubbf ySrS (46)
where Sf is the flame speed and yb = Vb /(Vc - Ve ) is the burned gas volume fraction. Note that for
yb=0, Sf = (u/b)Sb and for yb=1, Sf = Sb.
The gas speed is defined by
ug = Sf -Sb (47)
Substituting Eq. 46 into Eq.47 we obtain
ug = Sb (u/b-1)(1-yb) (48)
This completes the equations for the burning model.
126
6.4. Comparison of Experimental Data with Model Predictions
For comparison with experimental results, the burning speeds of steady laminar adiabatic
one-dimensional pre-mixed methane/oxygen/diluent flames have been computed using the
SANDIA PREMIX code [49], marketed by Reaction Design. A reaction mechanism involving
53 species and 325 elementary reactions was taken from GRI-Mech 3.0 [7]. This mechanism is
optimized for burned gas temperatures from approximately 1000 to 2500 K, pressures from 10
Torr to 10 atm, and equivalence ratio from 0.1 to 5 [7]. It was chosen for the calculations
because it has been widely used for laminar flame speed calculations.
The comparisons were made for a wide range of conditions spanning both the high and
low temperature regimes. The conditions, under which significant cracking or wrinkling
occurred, were observed and are reported. A mixture of 86 % N2 and 14 % CO2 is used for the
extra diluent to simulate the molar mass and specific heat of the exhaust gas in internal
combustion engines. Observations of the flame structure were carried out in the cylindrical
chamber. Although this vessel is not spherical, the flame propagates spherically over 90 percent
of the distance to the wall. Shadowgraph photographs of flame fronts for stoichiometric
methane-air-diluent mixtures with initial pressure and temperature of 1.0 atm and 298 K are
shown in Figure 2 for 0-15% diluent. In these photographs, the final pressure is approximately 5
times the initial pressure. It can be seen that at all conditions, the flame front is smooth and
spherical except for a single crack near the top, extending between the electrodes. This suggests
that cracking may be caused at least in part an interaction between the flame front and the
electrodes.
The corresponding burning speeds along isentropes computed from the pressure rise in
the spherical chamber are shown by the solid points in Figure 3. All the measured values are for
smooth flames with large radii and therefore represent laminar adiabatic burning speeds. The
solid lines show values calculated using PREMIX with GRI-Mech 3.0 kinetics. It can be seen
that adding diluent decreases both the burning speed and the final pressure achieved in the
vessel. The dependence of the flame speed on percentage of diluent is reproduced reasonable
well by the PREMIX calculations but the absolute values are roughly the 10-15% higher than the
measurements for all conditions. This is within the uncertainty of the rate constants used in the
GRI kinetics and could probably be corrected by minor adjustments.
Shadowgraph photographs of flame fronts for stoichiometric methane-air-diluent
127
mixtures with initial pressure and temperature of 5 atm and 298 K are shown in Figure 4 for 0-
15% diluent. For the mixtures with zero diluent shown in part a, cracking can be seen for
p/pi=1.03 while for p/pi=1.4, the flame is cellular. Parts b-d show that adding diluent results in
flames that are cracked but not cellular. As the percentage of diluent increases the degree of
cracking decreases indicating a more stable flame front. For 15% diluent, buoyant rise of the
very slow flame can be observed.
Figure 5 shows the measured burning speeds corresponding to Fig 4. Solid symbols refer
to cracked flames and open symbols to cellular flames. The results of PREMIX calculations are
shown by the solid lines. Again as the percentage of diluent increases the burning speed
decreases. It can be seen that the agreement between measured values and PREMIX calculations
is reasonably good for cracked flames with 0-15% diluent. However for cellular flames with
zero diluent, the measured burning speeds are substantially higher than PREMIX calculations.
This may be due to an increased effective burning area for cellular flames.
Shadowgraphs of lean methane-air-diluent flames with equivalence ratio =0.8 and
initial pressure and temperature of 5 atm. and 298 K are shown in Fig. 6 for 0-15% diluent. All
the flames in this figure show some cracks. Parts a-b show that for 0-5% diluent, cells appear on
the flame surface at the highest pressure ratios. Parts c-d show buoyant rise and distortion of the
slow flames with 10-15% diluent. Ionization probes mounted flush with the wall at the top and
bottom of the chamber were used to check the degree of distortion and buoyant rise rate. Within
the estimated experimental error of 5%, the burning areas for distorted flames determined from
the shadowgraphs were equal to those calculated from the pressure data for spherical flame of
the same volume. This shows that distortion of the flame front can be quite large before the
expected increase in flame area becomes observable.
Figure 7 shows a comparison of the measured burning speeds with PREMIX calculations
for the lean flames shown in Fig. 6. Cracked flames are shown by solid symbols and cellular
flames by hollow symbols. PREMIX calculations are shown by solid lines. As previously seen in
Fig 5, the measured burning speed for the cellular flames observed for 0% and 5% diluent are
higher and have larger temperature coefficients than those calculated using PREMIX. For
cracked flames at 0-5% diluent, the measured burning speeds agree fairly well in magnitude with
PREMIX calculations but have a larger temperature coefficient. As the diluent is increased to 10-
15%, the measured burning speeds drop below the PREMIX values.
128
Shadowgraphs of flame propagation for rich methane-air-diluent mixtures with
equivalence ratio = 1.2 and initial pressure and temperature of 5 atm and 298 K are shown in
Figure 8 for 0-10% diluent. For all diluent fractions, the flames are smooth with very few cracks
but some distortion and buoyant rise apparent for slow flames.
The measured burning speeds of these flames are compared with PREMIX calculations in
Figure 9. It can be seen that the measured burning speeds are significantly lower than the
PREMIX values for all diluent fractions. Since these flames are smooth, this indicates a failure
of the GRI-Mech 3.0 kinetics as anticipated for high pressure rich flames. Other investigators
[57, 58] have also observed similar discrepancies between measured burning speeds and
calculations using GRI-Mech 3.0 kinetics at high pressures. The most probable reason for the
discrepancy is the omission of reactions involving alkyl peroxides from GRI-Mech 3.0 kinetics.
Corrections for radiation heat loss from the burned gas and conduction heat losses to the
electrodes and combustion chamber wall have all been included in the model used to calculate
the burning speeds from the pressure records and were less than 2% for all cases considered. The
corrections curvature and stretch associated with the preheat zone displacement volume were less
than 1% for flames with radii greater than 1 cm.
Acknowledgements
This research was partially supported by the Army Research Office, Grant No. DAAD19-01-1-
0587, under technical monitoring of Dr. David Mann and Dr. Ralph Anthenien. The authors
would like to thank Mr. Farzan Parsinejad, Mr. Soner Kahraman and Mr. Mat Matlo for their
help in data collection and reduction.
References
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133
TBurned Gas Unburned Gas
dph dbl
Ta
Tu
Tw
rb rc r
rcrb
Vb Vu
Reaction Sheet
Figure 1. Schematic of the combustion chamber showing the flame geometry and the
assumed radial temperature profile.
134
(a) dil =0% (b) 5% (c) 10% (d) 15%
t = 5 msec, p/pi = 1 t = 7 msec, p/pi = 1 t = 10 msec, p/pi = 1 t = 15 msec, p/pi = 1
t =15 msec, p/pi = 1.05 t = 17 msec, p/pi = 1.04 t = 25 msec, p/pi = 1.07 t = 40 msec, p/pi= 1.1
t =25 msec, p/pi=1.45 t = 30 msec, p/pi=1.47 t = 40 msec, p/pi = 1.5 t =53 msec, p/pi=1.29
Figure 2. Shadowgraphs showing flame propagation in the cylindrical chamber for
stoichiometric methane-air-diluent mixtures at several diluent fractions and =1.0, pi=1.0
atm, and Ti=298 K.
135
1 2 3 4 5 6 710
20
30
40
50
60
10%
15%
5%
0% diluent
Meas. Smooth Flame Premix
S b (cm
/sec
)
p (atm)
Figure 3. Comparison of measured burning speeds along isentropes with PREMIX
calculations for the same conditions as Fig. 2.
136
(a) dil = 0 % (b) 5 % (c) 10 % (d) 15 %
t = 3 msec, p/pi = 1 t = 3 msec, p/pi = 1 t = 3 msec, p/pi = 1 t = 20 msec, p/pi = 1
t = 14 msec, p/pi = 1.03 t = 19 msec, p/pi = 1.03 t = 29 msec, p/pi = 1.03 t = 80 msec, p/pi= 1.2
t =35 msec, p/pi=1.4 t = 50 msec, p/pi= 1.4 t =67 msec, p/pi=1.4 t =110 msec, p/pi=1.5
Figure 4. Shadowgraphs showing flame propagation in the cylindrical chamber for
stoichiometric methane-air-diluent mixtures at several diluent fractions and =1.0, pi=5.0
atm, and Ti=298 K.
g
g
137
300 320 340 360 380 400 420 440 460 4800
5
10
15
20
25
30
15%
10%
5%
0% Diluent
PREMIX
Cellular
S b (cm
/sec
)
Tu (K)
Cracked Flame
Figure 5. Comparison of measured burning speeds along isentropes with PREMIX calculations
for the same conditions as Fig. 4.
138
(a) dil=0% (b) 5% (c) 10% (d) 15%
t = 20 msec, p/ pi = 1.0 t = 20 msec, p/ pi = 1.0 t = 20 msec, , p/ pi = 1.02 t = 40 msec, p/ pi=1.0
t = 30 msec, p/ pi = 1.03 t = 40 msec, p/ pi = 1.03 t = 40 msec, p/ pi = 1.02 t= 80 msec, p/pi=1.03
t = 40 msec, p/ pi = 1.14 t = 60 msec, p/ pi = 1.14 t = 60 msec, p/ pi = 1.06 t=120msec p/ pi=1.11
t = 50 msec, p/ pi = 1.26 t = 80 msec, p/ pi = 1.33 t = 80 msec, p/ pi = 1.13 t=160msec,p/ pi=1.24
t = 60 msec, p/ pi = 1.48 t = 80 msec, p/ pi = 1.68 t = 123 msec, p/ pi = 1.41 t=180msec,p/ pi=1.36
Figure 6. Shadowgraphs showing flame propagation in the cylindrical chamber for lean
methane-air-diluent mixtures at several diluent fractions and =0.8, pi=5.0 atm, and
Ti=298 K.
g
g
139
300 320 340 360 380 400 420 440 4600
2
4
6
8
10
12
14
16
18
20
15%
10%
5%
0% Diluent
Cellalar
PREMIX
Cracked Flame
S b (cm
/sec
)
Tu (K)
Figure 7. Comparison of measured burning speeds along isentropes with PREMIX
calculations for the same conditions as Fig. 6.
140
(a) dil = 0 % (b) 5 % (c) 10 %
t= 12 msec, p/ pi = 1.0 t = 12 msec, p/ pi =1.0 t = 28 msec, p/ pi = 1.0
t = 37 msec, p/ pi = 1.07 t = 43 msec, p/ pi = 1.03 t = 92 msec, p/ pi = 1.1
t = 47 msec p/ pi =1.15 t = 93 msec, p/ pi = 1.35 t = 159 msec, p/ pi = 1.8
Figure 8. Shadowgraphs showing flame propagation in the cylindrical chamber for rich
methane-air-diluent mixtures at several diluent fractions and =1.2, pi=5.0 atm, and
Ti=298 K.
g
g
141
Figure 9. Comparison of measured burning speeds along isentropes with PREMIX calculations
for the same conditions as Fig. 8.
300 320 340 360 380 400 420 440 4600
5
10
15
20 PREMIX
Smooth FlameS b (cm
/sec
)
Tu (K)
10%
5%
0% Diluent
142
7. Flame Structure and Laminar Burning Speeds of
JP-8/air Premixed Mixtures at High Temperatures
and Pressures
Fuel 89(2010) 1041-1049
143
7. Flame Structure and Laminar Burning Speeds of
JP-8/air Premixed Mixtures at High Temperatures
and Pressures Kian Eisazadeh Far1, Farzan Parsinejad2 and Hameed Metghalchi1*
1) Department of Mechanical and Industrial Engineering,
Northeastern University, Boston, MA, 02115-5000, USA
2) Chevron Corporation, Richmond, CA, USA
* Corresponding Author:
Mechanical and Industrial Engineering
334 Snell Engineering Center, Northeastern University
360 Huntington Avenue, Boston, MA 02115, USA
Tel: (617) 373-2973
Fax: (617) 373-2921
E-mail: [email protected]
144
Abstract
Jet propellant 8 (JP-8)/air laminar burning speed was experimentally measured and its flame
structure was studied at high temperatures and pressures using a high-speed camera. The
experimental facilities included a spherical vessel, used for the measurement of burning speed,
and a cylindrical vessel, used in a shadowgraph system to study flame shape and structure, and to
measure burning speed. A thermodynamic model was developed to calculate burning speeds
using dynamic pressure rise in the vessel due to combustion process. The model considers a
central burned gas core of variable temperature surrounded by reaction sheet, unburned gas shell
with uniform temperature and thermal boundary layers at the wall and electrodes. Radiation from
burned gases to the walls was also included in the model. Burning speeds of laminar flames of
JP-8/air were calculated for a wide range of conditions. Power law correlation was developed at
temperatures ranging from 500-700 K, pressures of 1-6 atm and equivalence ratios of 0.8-1.
Flame structure and cell formations were observed using an optical system. Experimental results
showed that pressure and fuel air equivalence ratio have great influence on flame structure.
Keywords: JP-8, Laminar burning speed, flame structure, aviation fuels
7.1. Introduction
The United States Army and Air Force use JP-8 and Jet A-1 fuels as the main sources of
energy for military land vehicles and aircraft [1, 2]. The North Atlantic Treaty Organization
(NATO) has decided to use the same fuels in all battlefields under the ‘Single Fuel Concept’ [2,
3]. JP-8 and Jet A-1 have similar chemical structures because JP-8 is formed from Jet A-1 using
some special additives to improve thermal stability characteristics [4]. JP-8 can be used as an
alternative for diesel fuel because of their similar thermal and chemical properties. Due to its
acceptable thermal stability parameters, its low freezing point of < -60 ˚C, and its dual
application as both a coolant and an energy source, JP-8 is widely applied to aircraft engines and
gas-turbines [1].
JP-8 is a complex chemical component composed of aromatics, n-paraffins, and
cycloparaffins [2, 5-6]. This complex component makes it difficult to develop any chemical
kinetics mechanism for this fuel. Some researchers try to identify surrogates for JP-8 with
similar thermo-physical and thermo-chemical properties [5-7]. Validation of the developed
chemical kinetics mechanism requires some reliable experimental data. Laminar burning speed is
145
one of the fundamental properties of every fuel which can be used to validate theoretical models.
It can also be used to correlate turbulent burning speeds. Laminar burning speed is strongly
affected by mixture characteristics such as equivalence ratio and diluent type, and operational
conditions such as temperature and pressure. Depending on the experimental facilities and
design, there are various methods for measurement of laminar burning speed [8-15]. The
flexibility of system to measure the laminar burning speeds at high temperatures and pressures is
very important.
Ji and co-workers [16] have measured the laminar burning speed of JP-8/air mixture at
atmospheric pressure, temperature of 403 K, and various equivalence ratios using an atmospheric
counter flow flame. They have also measured the laminar burning speeds of some other heavy
hydrocarbons and have compared those with JP-8 laminar burning speeds. However, there are no
published data about burning speed of JP-8 under conditions of combined high temperatures,
high pressures, and varying equivalence ratios. In this study the laminar burning speed of JP-8
has been measured at high temperatures and pressures. A thermodynamic model, , described in
section 4, using the I the pressure rise method has been employed [17-19]. A shadowgraph
optical system was used to observe the shape of the flames and ensure that they were laminar.
Finally, a correlation was developed for laminar burning speeds of JP-8/air as a function of
temperature, pressure, and equivalence ratio.
7.2. Experimental Facility
The experimental system includes a spherical chamber and a cylindrical vessel. Both the
spherical and cylindrical vessels were used to measure pressure rise caused by the combustion
process. The cylindrical vessel withstands a maximum pressure of 50 atmospheres, due to having
two end large windows, while the spherical vessel was used for maximum pressure of 425
atmospheres. The cylindrical vessel was used in a shadowgraph system which took pictures of
flame propagation. Both vessels were filled using a control system composed of valves, pipes
connected to the air, and a vacuum pump. Liquid fuel was stored in a liquid fuel reservoir which
was attached to a liquid fuel manifold. The liquid fuel manifold was equipped with two Cartidge
heaters to evaporate the liquid fuel. The liquid fuel was heated to evaporate completely before
entering the combustion chamber. The initial temperature of the liquid fuel manifold was equal
to the initial temperature of the combustion chamber. Ionization probes, screwed into the inner
walls, were used to determine flame arrival time to vessel walls. A data acquisition system was
146
used to capture the pressure-time data as well as the signals from the ionization probes. A
computer driven system has been used to make the mixture with required fuel and oxidizer and
to initiate the combustion process. Figure 1 shows a schematic of the experimental system.
Spherical Vessel: The spherical vessel was constructed from two hemispheres, bolted together
to form a sphere with a diameter of 15.24 cm. The hemispheres were constructed from 4140 steel
with a thickness of 2.54 cm to withstand internal pressures up to 425 atm. The vessel was filled
and evacuated through a 6 mm tube on its bottom. The vessel was fitted with two extended
spark plug electrodes which provided a central point ignition source for the chamber. The
ignition energy was fixed on 15 mJ. The chamber was also fitted with a piezoelectric pressure
transducer, two thermocouples for measuring internal temperature and outer wall temperature,
and three ionization probes which detected when the flame had reached the wall. The entire
vessel was contained in a large oven capable of elevating the vessel temperature to ~500K.
Cylindrical Vessel: The cylindrical vessel was constructed from 316 SS and measures 13.5 cm
in diameter and is 13 cm long. The vessel is fitted with 3.5 cm thick Fused silica windows at
both ends which are sealed to the chamber with o-rings. The windows allow the vessel to
operate to a pressure of 50 atm. The purpose of the windows is to provide a clear line of sight
through the vessel for a shadowgraph setup that allows real time recording of the combustion
event. The vessel is also fitted with band heaters which allow the vessel to be heated to a
temperature of 500K. The vessel is fitted with spark plugs that allow for central point ignition,
similar to the sphere’s, and thermocouples that measure the internal temperature of the chamber
and the temperature of the vessel walls.
Shadowgraph system: Figure 2 presents the layout of the shadowgraph system. The
shadowgraph system is setup with the cylindrical vessel to take optical recording of the
combustion event. A CMOS camera with the capability of taking pictures up to 40,000 frames
per second has been used for these experiments. The shadowgraph setup consists of 5
components which are shown in Figure 2. Starting from the light source, a pinpoint source of
light is captured by a spherical mirror 152.4 cm away which reflects the light in a 15.24 cm
circular beam which travels through the combustion vessel to the opposite spherical mirror.
Once the circular pattern hits this second mirror it is again focused into a pin point 152.4 cm
away onto the CMOS camera. The image that the camera receives with the shadowgraph system
is very sensitive to density variation in places and allows us too see the changes in density of the
147
mixture as the combustion takes place.
The goal of these experiments was to study the structure of JP-8 premixed flames and to find
the affective parameters of the burning speed of the JP-8/air mixtures. Each experiment was
performed at least three times at each operational condition. According to statistical methods,
three identical runs are sufficient in order to ensure that the confidence level of the experiment is
above 95% [20]. Experiments at each operational condition were performed using both vessels.
First, the experiments were performed using the cylindrical vessel to observe the shape and
structure of the flame. Next, by qualitative understanding of flame treatment, the same
experiments were done in the spherical chamber to measure the burning speed. Two goals were
pursued by doing this procedure: 1- study of the effect of different parameters which create
turbulization and cellularity of the laminar flames, 2- measurement of burning speed based on
laminar cases. It must be noted that the pressure and temperature of the mixture is independent
from the shape of the vessel. Figure 3 shows the comparison between the pressure data of
cylindrical and spherical vessel. It can be seen that as long as the flame has not reached the
cylinder vessel, pressure data are identical. In this figure it can be seen that the pressure of the
mixture in the cylindrical vessel decreases faster than the spherical one after reaching the wall.
This is due to energy transfer effects after touching the wall.
JP-8 is a blend of several components. The percentage and distribution of these components
depend on the refining process and other technical operational conditions which are beyond the
scope of this paper. More information about the manufacturing processes and types of this fuel
can be found in literature [21]. JP-8 fuel used in this research was JP-8-4658, which is a mixture
of Jet fuel and JP-8 additives: it was made in the Air Force Research laboratory. Table 1 shows
the general properties of this fuel.
One of the important and challenging issues in the combustion of JP-8 is the initial
temperature of experiments. The initial temperature must be close enough to the boiling point of
the fuel to ensure that at least 90% of the fuel has been evaporated. It must be noted that JP-8 is a
blend and improper evaporation will make serious errors in equivalence ratio of the mixture.
Based on the information provided in Table 1, the initial temperatures of combustion chamber
and liquid fuel manifold were constant at about 500 K. According to the distillation curves of JP-
8, at this temperature at least 90% of the fuel was vaporized and the desired mixture was
obtained.
148
7.3. Flame Structure
Experiments were made in the cylindrical vessel to study flame structure for a wide range of
conditions. In these experiments, the variable parameters were equivalence ratio and initial
pressure of the mixture. The equivalence ratio was varied from 0.8 to 1 and initial pressures
were in the range of 1-3 atm. Figures 4 shows a series of snapshots of JP-8/air flames for fuel-air
equivalence ratio of 0.8 and initial pressures of 1, 2 and 3 atmospheres. It can be seen that flame
becomes cellular as pressure increases. Figures 5 and 6 present the same type of information for
fuel-air equivalence ratio of 0.9 and 1. Two major results are observed in the pictures: 1-
instability, and ultimately turbulence, originates from cells in the flame which form with
increasing pressure; 2- cell formation develops earlier as the mixture becomes richer. There are
some disturbances from the electrodes causing cracks which grow by propagating the flame. The
cracks impose a slight deformation on flame but the instability associated with small cells on the
flame appears suddenly in a certain pressure and radius. The cells appear simultaneously and
cover whole surface of the flame. The reason for cell formation and instability are due to
hydrodynamic and thermo-diffusive effects which are beyond the scope of this paper. Table 2
summarizes the cell formation pressures and temperatures of JP-8/air mixtures at various initial
pressures and equivalence ratios. These parameters quantify the conditions at which cells are
appeared on all parts of the flame. It is seen in Table 2 that cell formation strongly depends on
the pressure and equivalence ratio. The cellularity pressure of the mixtures is in the same order
for different initial pressures. For = 0.8 cellularity pressure is about 6.1 atm, for = 0.9 it is
in the range of 4.8-5 atm, and for = 1 it is in the range of 4-4.2 atm. Figure 7 shows the results
of Table 2. These results demonstrate the importance of pressure in cell formation of premixed
flames. Initial pressure does not affect critical pressure (Pcr) at which the flame becomes cellular.
The reasons for these behaviors are the subjects of instability analyses in spherical premixed
flames which are beyond the scope of this paper, however more details can be found in other
works [22-25].
Since it is assumed that the unburned gas is compressed isentropically, the cell formation
temperature can be calculated by the following expression:
1
)(
i
cricr P
PTT (1)
149
Where Tcr and Pcr are the critical temperature and pressures of which cell formation begins, Ti
and Pi are the initial temperature and pressure and γ is the ratio of the specific heat at constant
pressure to the specific heat at constant volume. Both of the specific heat terms are a function of
temperature. While initial pressure is not significant, a critical pressure of cell formation exists
for each equivalence ratio. Another conclusion is that the cell formation pressure increases as the
mixture becomes leaner.
7.4. Burning Model
The theoretical model used to calculate the burning speed from the pressure rise is based on
one previously developed by Metghalchi and co-workers [9]. The model has been modified to
include corrections for energy losses due to the electrodes, radiation from the burned gas to the
wall, and the temperature gradient in the preheat zone. It is assumed that the gases in the
combustion chamber can be divided into burned and unburned gas regions separated by a
reaction layer of negligible thickness. The burned gas in the center of chamber is divided into n
number of shells, where the number of shells is proportional to the combustion duration. The
burned gas temperature of each shell is different but all burned gases are in chemical equilibrium
with each other. The burned gases are surrounded by a preheat zone ( ph ) having variable
temperature, which is itself surrounded by unburned gases. A thermal boundary layer ( bl )
separates the unburned gas from the wall. The effect of energy transfer from burned gas to the
spark electrodes is considered by a thermal boundary layer ( bl ). Figure 8 shows a schematic of
the model used in this work.
7.4.1. Governing Equations
The distribution of temperature in burned and unburned gas region can be achieved by
equation of state
RTpv (2)
In this equation p is the pressure which is measured within the chamber, v is the specific volume,
R is the specific gas constant and T is the temperature.
The mass conservation equation for the burned and unburned gas region is:
ieciuubbub RTVVpVVmmm /)( (3)
150
where m is the total mass of the chamber, mb is the mass of the burned gas zone; mu is the mass
of the unburned gas zone. Vc is the volume of the chamber and Ve is the volume of the spark
electrodes. In this equation, i denotes the initial conditions, and u and b denote the unburned and
burned gas conditions, respectively. is the average density and V is the volume of the gas.
The total volume of the gas in the combustion chamber is
ubeci VVVVV (4)
where
b bm
0
m
0 ebbsb VmdpTvmdpTvV ),(),( (5)
is the volume of the burned gas, vbs is the specific volume of the isentropically compressed
burned gas,
mdvvVeb
bseb )( (6)
is the displacement volume of the electrode boundary layers,
m
m phwbusbub
VVvx1mmdpTvV )(),( (7)
is the volume of the unburned gas, xb = mb/m is the burned gas mass fraction, vus is the specific
volume of the isentropically compressed unburned gas,
wb uswb mdvvV )( (8)
is the displacement volume of the wall boundary layer,
ph usph mdvvV )( (9)
is the displacement volume of the preheat zone ahead of the reaction layer.
The energy conservation equation is
ubrwei EEQQQE (10)
where Ei is the initial energy of the gas, Qe is the conductive energy loss to the electrodes, Qw is
the energy loss to the wall, Qr is the radiation energy loss,
151
eb
m
0 bs
m
0b EmdpTemdpTeEbb ),(),( (11)
is the energy of the burned gas, ebs is the specific energy of isentropically compressed burned
gas,
eb
bseb mdeeE )( (12)
is the energy defect of the electrode boundary layer,
)()(),( m
m phwbusbub
EEex1mmdpTeE (13)
is the energy of the unburned gas, eus is the specific energy of the isentropically compressed
unburned gas,
wb uswb mdeeE )( (14)
is the energy defect of the wall boundary,
ph usph mdeeE )( (15)
is the energy defect of the preheat layer.
Using ideal gas assumptions
)/( 1pvhe f (16)
where hf is the enthalpy of formation of the gas at zero degrees Kelvin and = cp/cv is the
specific heat ratio. By this relation equations 12, 14, and 15 can be written as
)/()/()( 1pV1mdvvpE bebb
eb
bseb (17)
)/()/()( 1pV1mdvvpE uwbu
wb
uswb (18)
)/()/()( 1pV1mdvvpE uphu
ph
usph (19)
It was shown in [18] that in the case of rapid compression such as constant volume combustion,
the compression work terms on the boundary layer may be neglected and the resulting equations
152
are
ebbebe E1pVQ )/( (20)
wbuwbw E1pVQ )/( (21)
The radiation energy loss from the burned gas was calculated using
4bbp
t
0 rr TV4tdtQQ )( (22)
where p is the Planck mean absorption coefficient and is the Stefan-Boltzman constant.
Finally, combining equations 4, 5, and 7 gives
mVVVvvxdvpTv phwbebusi
x
0 usbs
b
/)()),(( (23)
and combining equations 10, 11, and 13 gives
mQ1pVeexdepTe ruphusi
x
0 usbs
b
/))/(()),(( (24)
The above equations have been solved for two unknowns: burned mass fraction, )(txb and
the burned gas temperature of the last layer, ),( trTb . Given pressure, )(tp as a function of time,
they can be solved numerically using the method of shells to obtain the burned mass fraction, as
a function of time and temperature distribution.
Ultimately, the burning speed may be defined as
bubbubb AxmAmS // (25)
where bA is the area of a sphere having a volume equal to that of the burned gas. More details
about the model can be found in [17-19, and 26].
7.5. Laminar Burning Speeds
All reported data are in regions where r/R > 0.4 (r and R are the radii of flame and chamber
respectively). In these regions the effects of stretch and spark discharge are very low. Spark
discharge creates a shock wave followed by an extremely high temperature region. It affects the
initial flame kernel propagation speed strikingly but as soon as the temperature of the hot core
153
drops and flame is large enough (r/R > 0.25) these effects are vanished [27 and 28]. Figures 9
and 10 show the laminar burning speed at three different equivalence ratios, initial temperature
of 500 K and initial pressures of 1 and 2 atm, respectively. As expected, by increasing the
equivalence ratio, laminar burning speed increases. Burning speed curves are plotted versus
unburned gas temperature on isentropic lines and it is seen that at higher temperatures, laminar
burning speed is increased. The oscillations observed in these figures are due to the acoustic
oscillations inside the chamber.
The measured laminar burning speed data have been fitted to the following power law
correlation
ouo
uuou P
P
T
TaaSS ))1()1(1( 2
21 (26)
where Suo is the burning speed at reference point (Po = 1 atm, Tuo = 500 K and 1 ). is the
mixture equivalence ratio, Tu is the unburned gas temperature in K, Tuo is the reference
temperature and equal to 500 K, P is the mixture pressure in atm and Po is the reference pressure
and equal to 1 atm. a1, a2, and are constant. Using a nonlinear least square method the
values are Suo = 93.6 cm/s, a1 = - 0.22, a2 = - 4.4, = 2.13 and = -0.18. The negative pressure
exponent -0.18 results in an overall order of reaction of less than two for the combustion process,
which is consistent with general understanding.
This correlation is only for laminar burning speed of JP-8-air flames. It is valid in the
pressure range of 1 < P < Pcr, temperature range of 500 < Tu < Tcr and equivalence ratio range of
0.8 < < 1.0. Pcr can be found from Table 2 and Tcr can be calculated from equation 1. Figure
11 shows the burned mass fraction rate ( )(txb ) of JP-8/air mixtures at initial pressure of 5 atm
and initial temperature of 500 K in three different equivalence ratios. According to Table 2, all of
the presented data in this figure belongs to cellular flames. The data demonstrates that in early
stages the slope is linear but as pressure increases the slope becomes non-linear. This trend is
more obvious at equivalence ratio of 1. At higher pressures, more cells are formed. These cells
increase the surface the flame, which increases mass burning rate.
Acknowledgement
This work has been done by the generous support of Army Research Office (ARO)
154
corresponding to Grant No. W911NF0510051. Kind guidance of Dr. David Mann and Dr. Ralph
Anthenien, ARO (Army research Office) is appreciated. The authors would like to thank Dr. Tim
Edwards, AFRL (Air Force Research Laboratory) for providing the fuels.
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157
Table 1: Cell formation analysis of JP-8/air mixtures
Property Results
Distillation
Initial boiling point (K)
10% recovered (K)
20% recovered (K)
50% recovered (K)
90% recovered (K)
Final boiling point (K)
320
426
435
450
481
498
Flash point (K) 311
Density (kg/L) 0.81
Viscosity (mm2/s @253 K) 2.12
Heat Value, heat of combustion: (MJ/kg) 42.79
158
Table 2: Cell formation analysis of JP-8/air mixtures
Pi = 1 atm Pi = 2 atm Pi = 3 atm
0.8
Non-cellular
Non-cellular
Pcr ~ 6.1 atm
Tcr ~ 587 K
0.9
Pcr ~ 4.7 atm
Tcr ~ 705 K
Pcr ~ 5.1 atm
Tcr ~ 614 K
Pcr ~ 4.8 atm
Tcr ~ 554 K
1
Pcr ~ 4.2 atm
Tcr ~ 690 K
Pcr ~ 4.05 atm
Tcr ~ 583 K
Pcr ~ 4.1 atm
Tcr ~ 534 K
159
Figure 1: Schematic Diagram of Experimental Facilities
160
Figure 2: Sketch of the Shadowgraph System
161
Time (ms)
Pre
ssu
re(a
tm)
0 10 20 30 40 500
5
10
15
20
25
30
35 Cylindrical vesselSpherical vesselFlame arrival to the wallin cylindrical vessel
Figure 3: Comparison between the pressure data of JP-8/air mixture in cylindrical and spherical
vessels, = 0.8, Ti = 500 K, Pi=5 atm
162
a. Pi=1 atm b. Pi=2 atm c. Pi=3 atm
P/Pi = 1.3 P/Pi = 1.3 P/Pi = 1.3
P/Pi = 1.75 P/Pi = 1.75 P/Pi = 1.75
P/Pi = 2.55 P/Pi = 3.25 P/Pi = 3.25
Figure 4: JP-8/air mixture = 0.8, Ti = 500 K,
163
a. Pi=1 atm b. Pi=2 atm c. Pi=3 atm
P/Pi = 1.14 P/Pi = 1.14 P/Pi = 1.14
P/Pi=1.55 P/Pi = 1.55 P/Pi=1.55
P/Pi = 3.25 P/Pi = 3.25 P/Pi = 3.25
Figure 5: JP-8/air mixture = 0.9, Ti=500 K,
164
a. Pi=1 atm b. Pi=2 atm c. Pi=3 atm
P/Pi = 1.21 P/Pi = 1.21 P/Pi = 1.21
P/Pi = 1.55 P/Pi = 1.55 P/Pi = 1.55
P/Pi=3.25 P/Pi=3.25 P/Pi = 3.25
Figure 6: JP-8/air mixture = 1, Ti=500 K,
165
Equivalence Ratio
Pre
ssu
re(a
tm)
0.7 0.8 0.9 1 1.13
3.5
4
4.5
5
5.5
6
6.5
7Pi=1 atmPi=2 atmPi=3 atm
Cellular
Non-Cellular
Figure 7: Cell formation pressures of JP-8/air mixtures at various initial pressures and
equivalence ratios, Ti = 500 K,
166
Figure 8: Schematic of different zones and their corresponding temperatures in the
thermodynamics model
167
Temperature (K)
La
min
ar
Bu
rnin
gS
pe
ed
(cm
/s)
500 550 600 650 70060
70
80
90
100
110
120
130
140 = 1 = 0.9 = 0.8Power law fit
Figure 9: Laminar burning speeds of JP-8/air mixture at Ti = 500 K, Pi = 1 atm, and equivalence
ratios of 0.8, 0.9 and 1
168
Temperature (K)
La
min
ar
Bu
rnin
gS
pe
ed
(cm
/s)
500 550 600 65060
70
80
90
100
110
120 = 1 = 0.9 = 0.8Power law fit
Figure 10: Laminar burning speeds of JP-8/air mixture at Ti = 500 K,
Pi = 2 atm, and equivalence ratios of 0.8, 0.9 and 1
169
Pressure (atm)
Bu
rne
dM
ass
Fra
ctio
nR
ate
(1/s
)
5 10 15 20 25
0.01
0.02
0.03
0.04
0.05
0.06
0.07
0.08
0.09
0.1
0.11
0.12
0.13
0.14
0.15 = 1 = 0.9 = 0.8
Figure 11: Burned mass burning rate of JP-8/air mixture at Ti = 500 K,
Pi = 5 atm, and equivalence ratios of 0.8, 0.9 and 1
170
8. The Effect of Diluent on Flame Structure and
Laminar Burning Speeds of JP-8/oxidizer/diluent
Premixed Flames
Submitted to Fuel
171
8. The Effect of Diluent on Flame Structure and
Laminar Burning Speeds of JP-8/oxidizer/diluent
Premixed Flames
Kian Eisazadeh-Far1, Ali Moghaddas, Hameed Metghalchi1, and James C Keck2
1: Northeastern University, Boston MA 02115
2: Massachusetts Institute of Technology, Cambridge, MA 02139
Abstract
Experimental studies have been performed to investigate the flame structure and
laminar burning speed of JP-8/oxidizer/diluent premixed flames at high temperatures
and pressures. Three different diluents including argon, helium, and a mixture of 14%
CO2 and 86% N2, were used. The experiments were carried out in two constant volume
spherical and cylindrical vessels. Laminar burning speeds were measured using a
thermodynamics model based on the pressure rise method. Temperatures from 493-680
K and pressures from 1-10 atm were investigated. Extra diluent gases (EDG) decrease
the laminar burning speeds but do not greatly impact the stability of the flame
compared with JP-8/air. Replacing nitrogen in the air with argon and helium increases
the range of temperature and pressure in the experiments. Helium as a diluent also
increases the temperature and pressure range of stable flame as well as the laminar
burning speed. Power law correlations have been developed for laminar burning speeds
of JP-8/air/EDG and JP-8/oxygen/helium mixtures at a temperature range of 493-680 K
and a pressure range of 1-10 atm for lean mixtures.
Keywords: JP-8, laminar burning speed, combustion instability, diluent
8.1. Introduction
Jet Propellant-8 (JP-8) is a fuel currently used in land based engines and aviation combustors. It
172
would be beneficial to extend the application of this fuel under the framework of the “Single
Fuel Concept” [1]. There are several theoretical studies underway to develop the chemical
kinetics mechanism of this complex fuel. Validation of these mechanisms requires reliable,
highly accurate experimental data. These experimental data should be available in a wide range
of temperatures, pressures and equivalence ratios. Laminar burning speed, which is a
fundamental property of each fuel, can be used to provide experimental data for chemical
kinetics mechanisms. It is also used for the correlation of turbulent flame propagation in internal
combustion engines. Currently some experimental and theoretical data exists in the literature
about the laminar burning speeds of JP-8 fuel at atmospheric pressures and high temperatures [2-
4]. Ji et al [2] measured the laminar burning speed at a temperature of 403 K and atmospheric
pressure. They used a counter-flow flame experimental facility to estimate the laminar burning
speeds after stretch corrections. Kumar et al [3] measured the laminar burning speeds of Jet-A
fuels and other heavy hydrocarbons at a temperature of 470 K and atmospheric pressure by a
counterflow flame similar to Ji et al. These data are reported in a limited range of temperatures
and pressures. In most combustors, such as internal combustion engines, fuel is burned at high
temperatures and pressures, therefore the measurement of laminar burning speeds under those
conditions is essential.
Eisazadeh-Far et al [5] measured the laminar burning speeds of JP-8/air mixtures at a
temperature range of 500-700 K, pressures of 1-6 atm and equivalence ratios of 0.8-1. They
concluded that JP-8/air flames are sensitive to instability at high temperatures and richer
mixtures. Burning speeds for smooth flames were measured by the pressure rise method and a
power law fit correlation for laminar burning speed calculation was developed.
This paper investigates the effect of diluent type on the stability and laminar burning speeds
of JP-8/air/EDG and JP-8/oxygen/(argon, helium) flames. The effect of EDG addition to JP-
8/air/EDG on flame structure will be studied in a wide range of temperatures, pressures and
equivalence ratios. Following the flame structure study, laminar burning speeds of JP-8/air/EDG
and JP-8/oxygen/helium will be reported at temperatures of (493-680 K) and higher pressures (1-
10 atm) compared to previously published results for JP-8/air flames [5].
8.2. Experimental Facility
Experiments have been performed using two constant volume cylindrical and spherical vessels.
173
Figure 1 shows the general configuration of the experimental set up. The cylindrical vessel is
located in a shadowgraph system to take snapshots of flame propagation. It is equipped with two
end windows, which can withstand pressures and initial temperatures up to 50 atm and 500 K
respectively. The images are taken using a CMOS camera capable of taking pictures up to
40,000 frames per second. Figure 2 shows the configuration of the shadowgraph system. The
spherical vessel is made of stainless steel which can withstand pressures up to 400 atm. It is
located in an oven which can heat up the vessel to 500 K. Both vessels are used for laminar
burning speed measurements. More information about the experimental facilities and procedure
of the tests can be found in previous publications [5-7].
8.2.1. Vapor pressures and Temperatures
JP-8 is a blend of several chemical components. Setting up the proper initial temperature close to
the boiling temperature is essential. A VARIAN CP-3800 Gas-Chromatography system was used
to detect several analytes in JP-8 fuel. A chromatograph of gaseous JP-8 fuel is shown in Figure
3. It can be seen that C10, C11, and C12 are the dominant components of the mixture, which is in
agreement with the observation of other researchers [8, 9]. The boiling temperature of JP-8 fuel
should be close to that of the C10 and C11 hydrocarbons. The distillation, boiling point and other
properties of the applied JP-8 fuel are presented in Table 1. The fuel used in this study has been
provided by Air Force Research Laboratory (AFRL). The initial temperatures for all experiments
have been fixed at a constant temperature of 493 K at which the liquid fuel is vaporized
completely.
8.2.2. Fuel Cracking at High Temperatures
In both the cylindrical and spherical vessels the temperature of the unburned gases increases due
to the propagating flame acting as a piston. In our experiments the temperature range is
approximately 500-700 K. Thermal cracking of the fuel can cause serious errors in the burning
speed results, thus it is necessary to determine if there is any thermal cracking of the fuel in this
range. Edwards [10] has done several studies on the cracking and deposition of hydrocarbon
aviation fuels. An important part of his research concerns the endothermicity of the thermal
cracking process of hydrocarbons. He has concluded that for most of these endothermic
hydrocarbons, including JP-8, the thermal cracking temperature roughly begins at 750-810 K.
The thermal cracking process also depends on pressure which is intensified in higher pressures
174
[10-11]. The important factor in the thermal cracking process is the residence time, which
defines the degree of equilibrium composition of the mixture. The fuel residence times in this
study are defined by the combustion process and it are short enough to ensure that cracking will
not occur [5, 12-13]. Also, the range of temperatures and pressures in this paper never exceed the
critical cracking temperatures and pressures expressed in literature [10, 14-15].
8.3. Experimental Results and Discussion
8.3.1. Experiments with Air and EDG
Experiments with EDG have been performed with volumetric percentages of 5% and 10%.
Initial conditions were fixed at an initial temperature of 493 K, initial pressures of 1, 2, and 3 atm
and equivalence ratios of 0.8, 0.9 and 1. Table 2 shows the initial conditions of the experiments.
The first set of experiments was carried out in the cylindrical vessel to investigate flame
structure. All pictures were taken by CMOS camera at 10,000 frames per second with a high
resolution. Figure 4 shows the snapshots of stoichiometric JP-8/air mixtures without EDG with
three different initial pressures. The first observation is that for lean JP-8/air mixtures increasing
the equivalence ratio and pressure enhances the instability. There are some cracks on the flame
around the electrodes which are due to the disturbances from the spark electrodes and which
develop as the flame grows. However, smaller cells appear afterwards simultaneously all over
the flame surface at critical radii.
Flame instability originates from the disturbances imposed into the flame by various sources
such as spark, interactions with electrodes, density gradient, stoichiometry gradient in the
mixture, etc.. These disturbances are unstable if their growth rate is higher than the flame growth
rate. The mechanisms which cause and amplify the disturbances define the type of instability.
For example, heat diffusivity which is lower than mass diffusivity amplifies the growth rate of
perturbations and leads to thermo-diffusive instability [17-20]. Another type is hydrodynamics or
Rayleigh-Taylor instabilities in which flame becomes unstable due to disturbances associated
with thermal expansion [17-20]. The parameter which distinguishes the thermo-diffusive
instability from the hydrodynamic instability is the Lewis number ( mDLe / ) which is a non-
dimensional parameter. It is the ratio of thermal diffusivity, , to mass diffusivity, Dm, of
deficient reactant in the flame. When Le<1, the observed instability of the flame is thermo-
diffusive. Since the corresponding Le number of lean hydrocarbon-air mixtures with more than
three carbons is larger than unity [21-24], the instabilities observed in our experiments can not be
175
thermo-diffusive. The other evidence is that thermo-diffusive instabilities usually develop right
after ignition, but for hydrodynamic instabilities there is a critical radius after which instability
grows; the later case is observed in our experiments [17, 18, and 20].
Figure 4 shows the images of JP-8/air flames at various initial pressures. This figure
demonstrates that flame is more sensitive to instability at higher pressures. At higher pressure
flame thickness decreases which reduces its resistance to perturbations and instabilities. Table 3
shows the cell formation temperatures, pressures and expansion ratios (σ = bu / )
corresponding to Fig 4. Cell formation has been observed in other experimental investigations as
well [17, 18, 25, and 26]. In addition to the effect of pressure on flame thickness, Oran and
Gardner [27] state that larger pressure pulses increase the amplitude of perturbations in premixed
flames. They show that the vorticity generation (baroclinic vorticity growth) is stimulated by
large pressure pulses along with an abrupt density gradient across the flame which consequently
causes cell formation and hydrodynamic instabilities [26, 28]. As such, thinner flames result in
larger density gradients ( )/1( ) which boosts vorticity generation. The role of pressure is
important both in thermo-diffusive and hydrodynamic instabilities. Yuan et al [29] have shown
in a theoretical investigation that for several Le numbers, increasing pressure extends the
unstable range in premixed flames. This theory is in agreement with experimental observations
obtained in this study.
It was also observed that flame instability occurs as the equivalence ratio increases. For a
heavy hydrocarbon mixture such as JP-8/air, enriching the mixture by fuel causes the deficiency
of the light reactant; it lowers the Le numbers and it causes earlier instability development [30].
Bechtold and Matalon [20] have shown that the critical radius Rcr from which instability begins
can be given by the relation, 2* /)(~ LeLeER acr , where is the flame thickness, Ea is the
activation energy, Le* <1 is the critical Le number and is the expansion ratio. This relation
shows that smaller Le numbers result in smaller critical radii.
Figure 5 shows the effect of EDG on flame structure in flames with an initial pressure of 3
atm, initial temperature of 493 K and three different volumetric percentage of diluents which are
0%, 5% and 10% respectively. In these snapshots it is seen that addition of EDG does not have a
remarkable effect on the stability of the flame. Tables 4 and 5 show the cell formation
temperatures, pressures and expansion ratios at various experimental conditions.
176
An important issue in these experiments is that cells are formed at large radii; for all of
reported cases rcr/R > 0.5. Bechtold and Matalon [20] state that for Le > Le* the onset of flame
instability is delayed until a critical radius is reached. In outwardly propagating spherical flames
the stretch factor = )/)(/2( dtdrr decreases by growing the flame. In lean mixtures of heavy
hydrocarbons it can be a decelerating factor since the Le number is larger than unity. In these
cases, stretch and curvature is a suppressing factor against instabilities [26, 31-32]. Liu et al [31]
have shown numerically that when flame is accelerating the disturbances from burned gas are
unstable, but if the flame decelerates the disturbances are stable. They have concluded that in
outwardly propagating spherical flames, stretch can slow the growth of instabilities. Bradley et al
[32] and Jomass et al [18] have shown experimentally that at constant temperatures and
pressures, spherical flames of heavy and partially heavy hydrocarbons become cellular at larger
radii where stretch is not strongly dominant. To understand the role of flame location on
instability an attempt was made to normalize the critical radius. The non-dimensional number is
the Peclet number (Pe) which is the ratio of flame thickness to flame radius ( /rPe ). The
critical Peclet number (Pec) characterizes the normalized flame radius at which there is a
transition to cellularity. To estimate the Pec the thickness of flame must be determined. There are
several techniques for calculation of [18, 23, and 33]. In this study it has been assumed
that up Sc / . In this equation, is the heat conductivity, is density, pc is the heat
capacity, and uS is the burning speed. Figure 6 shows the variation of critical Peclet numbers
with equivalence ratios for JP-8/air/EDG mixtures. Figure 6 shows that for lean JP-8/air
mixtures, Pec decreases by increasing the equivalence ratio. This figure indicates that in richer
mixtures flame becomes cellular at smaller radii. Thus by decreasing the Le number, the
premixed flame becomes more sensitive to hydrodynamic instabilities. Jomass et al [18] reached
the same conclusion by investigating critical Pec for near-equidiffusive and non-equidiffusive
flames. They have concluded that for non-equidiffusive mixtures, Pec numbers associated with
hydrodynamic instabilities decrease almost linearly by increasing the equivalence ratios. This
indicates that heat and mass diffusion have a striking influence on flame structure.
8.3.2. Experiments with Helium and Argon
One of the goals of this research is to extend the range of laminar flames to higher temperatures
and pressures. To this end nitrogen was replaced by helium and argon to investigate the effect on
flame structure. Helium and argon have equal heat capacities which are smaller than air.
177
Adiabatic flame temperatures of the mixtures with helium and argon are greater than mixtures
with air due to the difference in heat capacity. In addition, higher values of vp cc / result in
higher temperatures of the unburned gas during the isentropic compression. Figure 7 shows the
adiabatic flame temperature of stoichiometric JP-8 mixtures with air and O2+He versus
temperature.
Figure 8 shows the snapshots of JP-8/oxygen/(nitrogen, argon, helium) mixtures at initial
temperatures of 493 K and initial pressure of 2.5 atm. It can be seen that argon as diluent is the
worst option for flame stabilization. Critical pressures of JP-8/oxygen/argon flames are lower
than critical pressures of JP-8/oxygen/nitrogen and JP-8/oxygen/helium flames. This can be due
to the lower heat conductivity of argon and consequently lower thermal diffusivity which can
enhance the instability. Helium as diluent is the best option for producing stable flames at higher
temperatures and pressures. Compared to argon and nitrogen, helium has the highest heat
conductivity and can smooth out and consequently stabilize the flame [19, 30]. Figure 9 shows
JP-8/oxygen/helium flames at initial temperature of 493 K, initial pressure of 4 atm, and at
different equivalence ratios. It can be seen that helium increases the stability range of JP-
8/oxygen/helium flames compared with JP-8/air/EDG. Again, increasing the equivalence ratio
causes flame instability. The higher thermal diffusion of JP-8/oxygen/helium flames compared
with JP-8/air overshadows the hydrodynamic effects on instability. Figure 10 shows the critical
expansion ratios for JP-8/oxygen/helium and JP-8/air flames versus the normalized pressure.
This figure indicates that compared with JP-8/air flames, resistance of the JP-8/oxygen/helium
flame against the disturbances associated with thermal expansion increases. Sivashinsky [19]
states that thermo-diffusive processes play the first role in flame instability. Table 6 shows the
cell formation pressures, temperatures and critical expansion ratios of JP-8/oxygen/helium
mixtures at different initial pressures and equivalence ratios. Once again it is demonstrated that
the cellularity is strongly dependent on equivalence ratio and pressure. In the case of JP-
8/oxygen/helium flames cell formation occurs at higher temperatures and pressures compared to
air.
8.4. Burning Speed Measurements
8.4.1. Burning Model
There are several methods used to measure the laminar burning speed [33-39]. The theoretical
178
model used in this work to calculate the burning speed from the pressure rise is based on one
previously developed by Metghalchi and Keck [40]. The model has been modified to include
corrections for energy losses due to electrodes and radiation from the burned gas to the wall, as
well as the temperature gradient in the preheat zone. It is assumed that gases in the combustion
chamber can be divided into burned and unburned gas regions separated by a reaction layer of
negligible thickness. The burned gas in the center of chamber is divided into n number of shells
where the number of shells is proportional to the combustion duration. Burned gas temperature
in each shell is different but all burned gases are in chemical equilibrium with each other. The
burned gases are surrounded by a preheat zone ( ph ) having variable temperature, which is itself
surrounded by unburned gases. A thermal boundary layer ( bl ) separates the unburned gas from
the wall. The effect of energy transfer from burned gas to the spark electrodes is considered by a
thermal boundary layer ( bl ). Additional information about the model can be found in previous
publications [5 and 6].
As demonstrated in Rahim et al [6], volume and energy equations are solved simultaneously:
mVVVvvxdvpTv phwbebusi
x
0 usbs
b
/)()),(( (1)
mQ1pVeexdepTe ruphusi
x
0 usbs
b
/))/(()),(( (2)
where mVVv eci /)( and mEe ii / are the initial specific volume and energy of the
unburned gas in the chamber, bsv is the specific volume of isentropically compressed burned gas,
usv is the specific volume of isentropically compressed unburned gas. wbV , phV and ebV are
displacement volume of wall boundary layer, displacement volume of preheat zone ahead of the
reaction layer and displacement volume of electrode boundary layer respectively. bse , use , u
and rQ , are the specific energy of isentropically compressed burned gas, specific energy of
isentropically compressed unburned gas, specific heat ratio of unburned gas and radiation energy
loss from the burned gas zone, respectively. The above equations have been solved for two
unknowns: burned mass fraction and the burned gas temperature of the last layer. Given pressure
as a function of time, )(tp , they can be solved numerically using the method of shells to obtain
the burned mass fraction, )(txb , as a function of time and temperature distribution ),( trT .
179
Ultimately, the burning speed may be defined as:
bububu AxmAmS // (3)
where bA is the flame area.
All measurements are performed for laminar flames at radii (r>4 cm) to minimize the effects
of stretch. The reported laminar burning speeds in this study are the ones whose corresponding
flame stretch rates are lower than 70 1/s. In this range measured laminar burning speeds are
accurate enough that the effects of initial conditions such as spark fire can be neglected [5, 41-
42].
8.4.2. Laminar Burning Speeds
Burning speeds for laminar flames have been measured at high temperatures and pressures.
Given the measured values, power law fits have been developed by the least square method to
calculate the burning speeds of JP-8/air/EDG and JP-8/oxygen/helium mixtures. For JP-
8/air/EDG mixtures, the form of correlation is:
)1())1()1(1(00
2210 EDG
P
P
T
TaaSS
u
uuu
(4)
where Su0 is the burning speed at reference point (P0 = 1 atm, Tu0 = 500 K and 1 ) in cm/s,
is the mixture fuel-air equivalence ratio, Tu is the unburned gas temperature in K, P is the
mixture pressure in atm, and EDG is the diluent mole fraction. This correlation (4) is only valid
for smooth (laminar) flames, and the range of pressure and temperature depends on smoothness
of the flame which is a function of equivalence ratio and diluent type. Figure 11 shows the range
of pressures in which JP-8/oxidizer/diluent flames become cellular. The corresponding
temperature to each pressure can be found by following equation:
/)1()/( ii PPTT (5)
Table 7 shows the values of the constants in equation (4).
180
Table 7: Power law fit function coefficients of JP-8/air/EDG mixture
Suo (cm/s) a b α β θ
93.63 -0.22 -4.4 2.13 -0.185 3.52
Figure 12 shows the laminar burning speeds at three different EDG percentages. This figure
shows the measured and fitted values by equation (4). It is seen that laminar burning speed
decreases as EDG percentage increases. It is likely that the flame temperature decreases due to
increasing the heat capacity of the mixture. Regarding the effect of equivalence ratio, there is a
consistent behavior in burning speed values. In lean mixtures, laminar burning speed increases
by elevating the equivalence ratio. It can be estimated by Figure 12 that by increasing the EDG
fraction by 5%, the laminar burning speed decreases by about 15%. This highlights the
importance of EDG in JP-8/air/EDG flames. Addition of EDG to the mixture in internal
combustion engines usually decreases the power obtained. The reason can be attributed to slower
burning of the mixture which decreases the work production rate.
Same procedure of measuring and fitting was done for JP-8/oxygen/helium flames. The
power law fit correlation is
00
2210 ))1()1(1(
P
P
T
TaaSS
u
uuu (6)
where Su0 is the burning speed at reference point (P0 =4 atm, Tu0 = 500 K and 1 ). Table 8
shows the values of constants in equation 14.
Table 8: Power law fit function coefficients for the JP-8/oxygen/helium mixture
Suo (cm/s) a b α β
287.11 1.38 1.54 2.47 0.26
Correlation (6) is only valid for smooth (laminar) flames. Figure 11b shows the range of
pressures in which the flame is smooth. The corresponding temperatures can be calculated using
equation (4).
Figure 13 shows the measured and fitted laminar burning speeds of JP-8/oxygen/helium
mixtures at initial pressures of 4.5 and 5 atm, initial temperature of 493 K and equivalence ratios
of 0.8, 0.9, and 1. The percentage of helium is fixed at volumetric fraction of 79%. It is observed
181
that laminar burning speeds are tremendously higher than in JP-8/air mixtures. This can be
attributed to the higher flame temperature of JP-8/oxygen/helium mixtures due to the lower heat
capacity of helium. In addition, the heat conductivity of helium is greater which causes a higher
heat transfer rate to preheat zone from flame front which increases the rate of chemical reactions
and burning rate in the flame front.
Acknowledgment
This work has been done with the support of the Army Research Office (ARO), Grant No
W911NF0510051, under technical monitoring of Dr. David Mann and Dr. Ralph Anthenien. The
authors would like to thank Dr. Tim Edwards, Air Force Research Laboratory (AFRL), for
providing the fuels.
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Figure 1: The sketch of the experimental system
Figure 2: Shadowgraph system
186
Figure 3: Chromatograph of JP-8 (4658+additives)
C15H32
C16H34
C9H20
C10H22
C11H24 C12H26
C13H28
C14H30
C8H18
JP-8 (4658+additive)
187
a. Pi =1 atm b. Pi =2 atm c. Pi =3 atm
P/Pi = 1.21 P/Pi = 1.21 P/Pi = 1.21
P/Pi = 1.55 P/Pi = 1.55 P/Pi = 1.55
P/Pi=3.25 P/Pi=3.25 P/Pi = 3.25
Figure 4: Snapshots of JP-8/air flames at various initial pressures,
= 1, Ti = 493 K
188
EDG = 0 % EDG = 5% EDG = 10%
P/Pi=1.14 P/Pi=1.14 P/Pi=1.14
P/Pi=1.55 P/Pi=1.55 P/Pi=1.55
P/Pi=3.25 P/Pi=3.25 P/Pi=3.25
Figure 5: Snapshots of JP-8/air/EDG flames at several EDG percentages,
= 1, Ti = 493 K, Pi = 3 atm
189
Equivalence ratio ()
Pe
c
0.7 0.8 0.9 1 1.16000
7000
8000
9000
10000
11000
12000
13000
14000
15000 13
1415
16
17
18
19
2223
24
25
27
Figure 6: Critical Peclet numbers (Pec) versus equivalence ratio (experimental condition of each
number can be found at Table 2)
Unburned gas temperature (K)
Ad
iab
atic
flam
ete
mp
era
ture
(K)
450 500 550 600 650 7002000
2100
2200
2300
2400
2500
2600
2700
2800
2900
3000JP8/O2/HeJP8/air
Figure 7: Adiabatic flame temperature of stoichiometric JP-8/oxygen/diluent mixtures versus
unburned gas temperature
190
with nitrogen with argon with helium
P/Pi=1.21 P/Pi=1.22 P/Pi=1.24
P/Pi=1.53 P/Pi=1.69 P/Pi=2.14
P/Pi=2.47 P/Pi=2.52 P/Pi=3.04
Figure 8: Snapshots of JP-8/oxygen/diluent flames with different diluents (nitrogen, argon, and helium), = 1, Ti = 493 K, Pi=2.5 atm,
191
= 0.8 = 0.9 = 1
P/Pi=1.28 P/Pi=1.28 P/Pi=1.28
P/Pi=2 P/Pi=2 P/Pi=2
P/Pi=3.52 P/Pi=3.52 P/Pi=3.52
Figure 9: Snapshots of JP-8/oxygen/helium flames at different equivalence ratios,
Ti = 493 K, Pi=4 atm
192
Normalized critical pressure (Pcr/Pi)
Cri
tica
lexp
an
sio
nra
tio(
cr)
0 1 2 3 4 5 63.5
4
4.5
5
5.5 = 1, (21% O2+79% N2) = 1, (21% O2+79% He) = 0.9, (21% O2+79% N2) = 0.9, (21% O2+79% He)
Figure 10: Critical expansion ratios versus normalized critical pressures for mixtures with
different diluents and equivalence ratios
193
-
-
-
--
Pcr
0.7 0.8 0.9 1 1.13
4
5
6
7
8
EDG: 0%EDG: 5%EDG: 10%
-
cellular
smooth
(a)
+
+
+
++
++
Pcr
0.7 0.8 0.9 1 1.16
7
8
9
10
11
12
JP-8/O2/He+
cellular
smooth
(b)
Figure 11: Cell formation pressure versus equivalence ratio, a: JP-8/air/EDG,
b: JP-8/oxygen/helium
194
Unburned gas tmeperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
500 520 540 560 580 600 620 640 660 680 70040
50
60
70
80
90
100
110
120 EDG = 0 %EDG = 5 %Power law fit
Pi = 2 atm
= 0.8
Unburned gas temperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
500 520 540 560 580 600 620 640 660 680 70040
50
60
70
80
90
100
110
120 EDG = 0 %EDG = 5 %EDG = 10 %Power law fit
Pi = 2 atm
= 0.9
Unburned gas temperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
500 520 540 560 580 600 620 64040
50
60
70
80
90
100
110
120 EDG = 0 %EDG = 5 %EDG = 10 %Power law fit
Pi = 2 atm
= 1
Figure 12: JP-8/air/EDG laminar burning speeds at various EDG percentages and equivalence
ratios, Ti = 493 K, Pi = 2 atm
195
Temperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
500 525 550 575 600 625 650150
200
250
300
350
400 = 0.8 = 0.9 = 1Power law fit
Pi = 4.5 atm
Temperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
500 525 550 575 600 625 650150
200
250
300
350
400 = 0.8 = 0.9 = 1Power law fit
Pi = 5 atm
Figure 13: JP-8/oxygen/helium mixture laminar burning speed at several initial pressures and
equivalence ratios, Ti= 493 K
196
Table 1: JP-8 fuel properties
Fuel type JP-8: 4658+additives
Distillation
Initial boiling point (K) 320
10% recovered (K) 426
20% recovered (K) 435
50% recovered (K) 450
90% recovered (K) 481
Final boiling point (K) 498
Flash point (K) 311
Density (kg/L) 0.81
Viscosity (mm2/s @253 K) 2.12
Heat Value, heat of combustion: (MJ/kg) 42.79
197
Table 2 summary of experimental conditions for JP-8/air/EDG mixtures
test Pi Ti EDG %
1 1 493 0.8 0
2 1 493 0.8 5
3 1 493 0.8 10
4 1 493 0.9 0
5 1 493 0.9 5
6 1 493 0.9 10
7 1 493 1 0
8 1 493 1 5
9 1 493 1 10
10 2 493 0.8 0
11 2 493 0.8 5
12 2 493 0.8 10
13 2 493 0.9 0
14 2 493 0.9 5
15 2 493 0.9 10
16 2 493 1 0
17 2 493 1 5
18 2 493 1 10
19 3 493 0.8 0
20 3 493 0.8 5
21 3 493 0.8 10
22 3 493 0.9 0
23 3 493 0.9 5
24 3 493 0.9 10
25 3 493 1 0
26 3 493 1 5
27 3 493 1 10
198
Table 3: Cell formation analysis of JP-8/air mixtures
Pi = 1 atm Pi = 2 atm Pi = 3 atm
Pcr ~ 6.1 atm
0.8 smooth smooth Tcr ~ 587 K
σcr = 4.04
Pcr ~ 4.7 atm Pcr ~ 5.1 atm Pcr ~ 4.8 atm
0.9 Tcr ~ 705 K Tcr ~ 614 K Tcr ~ 554 K
σcr = 4.13 σcr = 4.41
Pcr ~ 4.2 atm Pcr ~ 4.05 atm Pcr ~ 4.1 atm
1 Tcr ~ 690 K Tcr ~ 583 K Tcr ~ 534 K
σcr = 4.39 σcr = 4.83
199
Table 4: Cell formation analysis of JP-8/air/EDG mixtures (EDG=5 %)
Pi = 1 atm Pi = 2 atm Pi = 3 atm
Pcr = 7.18 atm,
0.8 smooth smooth Tcr = 612 K
σcr = 3.79
Pcr = 4.38 atm, Pcr = 5.1 atm,
0.9 smooth Tcr = 596 K Tcr = 547 K
σcr = 4.13 σcr = 4.41
Pcr = 3.83 atm, Pcr = 4.06 atm,
1 smooth Tcr = 576 K Tcr = 515 K
σcr = 4.39 σcr = 4.83
200
Table 5: Cell formation analysis of JP-8/air/EDG mixtures (EDG=10 %)
Pi = 1 atm Pi = 2 atm Pi = 3 atm
0.8 smooth smooth smooth
Pcr = 5.32 atm Pcr = 5.7 atm,
0.9 smooth Tcr = 631 K Tcr = 560 K
σcr = 3.8 σcr = 4.2
Pcr = 3.77 atm Pcr = 4.37 atm
1 smooth Tcr = 575 K Tcr = 524 K
σcr = 4.33 σcr = 4.66
201
Table 6: Cell formation analysis of JP-8/oxygen/helium mixtures
Pi = 2 atm Pi = 3 atm Pi = 4 atm
Pcr = 11.2 atm Pcr =10.75 atm
0.8 smooth Tcr = 709 K Tcr = 640 K
σcr = 4.09 σcr = 4.47
Pcr =8.68 atm Pcr =8.24 atm
0.9 smooth Tcr = 658 K Tcr = 606 K
σcr = 4.54 σcr = 4.88
Pcr =8.04 atm Pcr =7.33 atm Pcr =7.59 atm
1 Tcr=707 K Tcr = 620 K Tcr = 590 K
σcr = 4.39 σcr = 4.93 σcr = 5.16
202
9. Laminar Burning Speeds of Ethanol/Air/Diluent
Mixtures
Accepted for publication in Proceedings of Combustion
Institute (33rd Symposium (International) on
Combustion))
203
9. Laminar Burning Speeds of Ethanol/Air/Diluent
Mixtures
Kian Eisazadeh-Far1*, Ali Moghaddas1, Jalal Al-Mulki2, Hameed Metghalchi1
1Department of Mechanical and Industrial Engineering,
Northeastern University, Boston, MA 02115-5000
2Damascus University, Damascus, Syria
* Corresponding Author:
Mechanical and Industrial Engineering
334 Snell Engineering Center, Northeastern University
360 Huntington Avenue, Boston, MA 02115, USA
Tel: (617) 373-3090
Fax: (617) 373-2921
E-mail: [email protected]
204
Abstract
Laminar Burning speed of ethanol/air/diluent mixtures have been measured over a wide range of
temperature, pressure, fuel air equivalence ratio and diluent. Experimental facilities include a
cylindrical vessel with two large end windows and a spherical vessel with capability to withstand
pressures up to 425 atmospheres. Both of these vessels are heated for having initial temperatures
of unburned gas up to 500 K. A shadowgraph system with a CMOS camera capable of taking
pictures up to 40,000 frames per second is used to observe structure of propagating flames.
Pressure rise due to combustion in both vessels is used to calculate laminar burning speed of the
mixture. A thermodynamic model is used to calculate burning speed from combustion pressure.
Laminar burning speeds of ethanol/air premixed mixtures have been measured at high
temperatures and pressures. A mixture of 86% nitrogen and 14% carbon dioxide, which simulate
heat capacity of residual gases in internal combustion engines, is used to determine the effect of
diluent on burning speed. A correlation for laminar burning speed as a function of temperature,
pressure, equivalence ratio and extra diluent gas (EDG) has been developed. The range of
temperature and pressure are 300-650 K and 1-5 atm, fuel air equivalence ratio 0.8-1.1 and extra
diluent gases of 5 and 10%. The measured values compare very well with available data and
extend the range many folds.
Keywords: Ethanol, biofuels, laminar burning speed, cell formation
205
Nomenclature
A Area
cp Constant pressure specific heat
cv Constant volume specific heat
e Energy
EDG Extra diluent gases
m Mass
P Pressure
Q Energy loss
r Flame radius
S Burning speed
t Time
T Temperature
v Specific volume
x Burned mass fraction
Greek letters
Temperature exponent
Pressure exponent
Ratio of specific heats
Thickness
Diluent exponent
Stretch rate
Equivalence ratio
Subscripts
b burned gas
bl thermal boundary layer
bs isentropically compressed burned gas
c chamber
e electrodes
eb electrode boundary layer
i initial condition
206
ph preheat zone
rad radiation
u unburned gas
us isentropically compressed unburned gas
wb wall boundary layer
9. 1. Introduction
Ethanol has been widely used in engines, land-based gas turbines for power production
and aircrafts [1-3]. It is important to learn more about the fundamental combustion properties of
this fuel. Laminar burning speed is a thermo-physical property which is used to analyze turbulent
flame propagation and it is also used to validate chemical kinetics models. Laminar burning
speeds of ethanol-air mixtures have been measured by some researchers recently. Bradley et al.
[4] have measured the laminar burning speeds of ethanol-air mixtures at pressures between 0.1
and 1.4 MPa, temperatures 300-393 K and equivalence ratios of 0.7-1.5. They have used a
constant pressure spherical vessel with optical access to do their experiments and then by using a
linear extrapolation for stretch effects; they have measured the laminar burning speeds. Gülder
[5] has measured the burning speeds at pressures and temperatures up to 0.8 MPa and 500 K
respectively over a wide range of equivalence ratios. Egolfopoulos et al [6] have measured the
laminar burning speeds of ethanol-air mixtures at atmospheric pressure using a counter-flow
flame in a temperature range of 363 and 453 K. Liao et al [7] have measured the laminar burning
speeds of ethanol-air mixtures at a temperature range of 300-480 K and pressure range of 1-10
atm. They have carried out their experiments in a wide range of equivalence ratios 0.7-1.4. There
are other experimental data in literature about burning speed and burning rate of ethanol but they
are in a limited range of temperatures and pressures [8, 9]. The effects of extra diluent gases
(EDG) on laminar burning speed and flame structure have not been investigated in any of
existing literature.
In this paper, laminar burning speeds of ethanol/air/diluent premixed mixtures have been
measured at higher temperatures (300-650 K) and pressures (1-5 atm), wide range of fuel air
equivalence ratios, and extra diluent gases (EDG). EDG is composed of 86% nitrogen and 14%
carbon dioxide to simulate residual gases in internal combustion engine. This mixture has the
same heat capacity of the burned gases in engines.
207
9.2. Experimental Facilities
The experimental system includes a spherical chamber and a cylindrical vessel. Both the
spherical and cylindrical vessels were used to measure pressure rise caused by the combustion
process. The vessels have been designed such that the ratio of volume to surface is equal. The
cylindrical vessel with two large end windows withstands a maximum pressure of 50
atmospheres while the spherical vessel withstands pressure of 425 atmospheres. Both vessels
were fitted with two extended spark plug electrodes which provide a central point ignition source
for the chamber. The vessels were equipped with heaters capable of elevating the vessel
temperature to 500 K. A shadowgraph system is used with cylindrical system to take images
from flame propagating flame. A CMOS camera with the capability of taking pictures up to
40,000 frames per second has been used in these experiments. A high speed data acquisition
system was used to record the pressure-time data. A computer driven system has been used to
make the mixture with required fuel and oxidizer and to initiate the combustion process. Method
of partial pressures has been used to set the initial fuel air equivalence ratio and verified using
gas chromatograph. A heated inlet manifold (500 K) has been used to have ethanol vapor. More
details about the experimental facility can be found in previous publications [10, 11].
9.3. Burning Model
The theoretical model used to calculate the burning speed from the pressure rise is based
on one previously developed by Metghalchi and co-workers [12-15] and has been modified to
include corrections for energy losses to electrodes and radiation from the burned gas to the wall
as well as inclusion of temperature gradient in the preheat zone. It is assumed that gases in the
combustion chamber can be divided into burned and unburned regions separated by a reaction
layer of negligible thickness. The burned gas in the center of chamber is divided into n number
of shells where the number of shells is proportional to the combustion duration. The burned
gases in each shell are assumed to be in chemical equilibrium with 28 species and have different
temperatures. The gases that burn early have higher temperature due to compression after
combustion. The burned gases are surrounded by a preheat zone ( ph ) having variable
temperature, which is itself surrounded by unburned gases. A thermal boundary layer ( bl )
separates the unburned gas from the wall. The effect of energy transfer from burned gas to the
spark electrodes is considered by a thermal boundary layer ( bl ). Volume and energy equations
208
described below are solved simultaneously:
mVVVvvxdvpTv phwbebusi
x
0 usbs
b
/)()),(( (1)
mQpVeexdepTe raduphusi
x
usbs
b
/))1/(()),((0
(2)
where mVVv eci /)( and mEe ii / are the initial specific volume and energy of the
unburned gas in the chamber, bsv is the specific volume of isentropically compressed burned gas,
usv is the specific volume of isentropically compressed unburned gas. wbV , phV and ebV are
displacement volume of wall boundary layer, displacement volume of preheat zone ahead of the
reaction layer and displacement volume of electrode boundary layer respectively. bse , use , u
and radQ , are the specific energy of isentropically compressed burned gas, specific energy of
isentropically compressed unburned gas, specific heat ratio of unburned gas and radiation energy
loss from the burned gas zone, respectively. The above equations have been solved for two
unknowns; burned mass fraction and the burned gas temperature of the last layer. Given
pressure, )(tp as a function of time, equations (1) and (2) can be solved numerically using the
method of shells to obtain the burned mass fraction, )(txb , as a function of time and temperature
distribution ),( trT .
Ultimately, the burning speed may be defined
bububu AxmAmS // (3)
Where, bA is the flame front area. In these experiments a 10% pressure rise is needed for
calculation which happens when flame radii become larger than 4 cm.
9.4. Results
Experiments were carried out in cylindrical and spherical vessels to observe flame
structure and to measure laminar burning speeds. The geometry of the vessel does not have a
significant effect on pressure data as shown in Fig. 1. It is clear that as long as flame has not
touched the wall in cylindrical vessel, the pressures in both vessels are very close to each other.
In cylindrical vessel the final pressure is lower than spherical vessel due to energy losses to the
wall after the hot gases are in contact with the wall.
209
Fig. 2 shows the snapshots of ethanol-air premixed flames at initial temperature of 450 K,
initial pressure of 1 atmosphere and three different equivalence ratios which are 0.8, 0.9, 1, and
1.1. As it can be seen the flames are fairly smooth. These snapshots demonstrate that as pressure
and flame radii increase, flames become more sensitive to cellularity. In this condition due to the
instability and consequent turbulence the area of flame increases abnormally and the
measurement of burning speed becomes extremely difficult. Cell formation is strongly a function
of pressure, flame radius, equivalence ratio and fuel type. In these experiments as well as other
researchers’ results, it has been observed that increase of pressure causes cell formation and
instability [16-19]. Another important parameter is the equivalence ratio. In this research,
enriching the mixture decreases the resistance of the flame against instabilities. It has been
shown that for heavy fuels, rich mixtures become unstable at lower pressures and temperatures
[16-19]. However, the analyses and the sources of flame instabilities are beyond the scope of this
paper and laminar burning speeds are reported for only stable and smooth flames.
Stretch effects: flame stretch is a phenomenon caused by the variation of flame area versus time.
In spherical flames the stretch rate is as following relation:
dt
dr
rdt
dA
A
21 (4)
where is the stretch rate, A is the area of flame, t is the time, and r is the radius of the flame.
Depending on the conditions, stretch can affect the laminar burning speed values. It is seen in
equation (4) that as the radius of flame increases the stretch rate decreases. In our measurements,
flame radii are larger than 4 cm, and stretch effects are negligible. In order to check the effect of
stretch in our experiments, laminar burning speeds of ethanol-air mixtures were measured at the
same temperatures, pressures, and equivalence ratios but with varying flame radii and stretch
rate. This is done by changing the initial temperature and pressure of the mixture along the
isentropic line. Fig. 3 shows temperature and pressure of unburned gas mixture for three different
experiments. Line AA’ is the locus of pressure and temperature for a stoichiometric mixture
having initial temperature of 300 K and 1 atmosphere pressure. As unburned gas ahead of flame
front compresses, both temperature and pressure of the mixture increases. Point A is the starting
condition and point A’ is the final condition of the unburned gas ahead of flame front. All points
on BB’ are conditions of another experiment having an initial condition of 2.5 atmospheres and
377 K temperature. Points on line CC’ show states of unburned gas mixture on another
210
experiment. Point M (T = 430 K, P = 4.5 atm) lies on all of these three isentropes while having
three different radii and different stretch rates. Laminar burning speed of flames at conditions
like point M having the same unburned gas properties but different radii ( r > 4 cm) and different
stretch rates have been determined and are shown in Fig. 4 as a function of stretch rate. As it can
be seen for two conditions shown with flame radii of larger than 4 cm and stretch rates of less
than70 1/s, burning speeds do not change. Numerous studies have shown that stretch rates higher
than 100 1/s can affect the laminar burning speeds [4-9]. Therefore, all reported laminar burning
speed data in this paper are for stretch rates lower than 70 1/s.
Laminar burning speeds: Fig. 5 shows laminar burning speeds of ethanol-air mixtures at various
initial conditions at four different equivalence ratios. It can be seen that for < 1.1, increasing
the equivalence ratio increases the burning speed. Fig. 5 shows laminar burning speeds along the
isentropic line versus temperature. The corresponding pressure to each temperature can be found
by following equation
/)1()/( ii PPTT (5)
In this equation vp cc / where cp is the specific heat at constant pressure and cv is the specific
heat at constant volume. Fig. 6 shows the effect of EDG on laminar burning speeds. This figure
indicates that addition of extra diluent gases decreases the laminar burning speed. This is due to
decreasing the adiabatic flame temperature by increasing heat capacity of the mixture.
In these figures the symbols are the measured laminar burning speed data by the model. The
solid line is a power law correlation developed for the burning speed data. The correlation is a
function of temperature, pressure, fuel air equivalence ratio and percentage of EDG in the
mixture as shown in equation (6):
)1(])1()1(1[00
2210 EDG
P
P
T
TaaSS uu
(6)
Where is the equivalence ratio, T is the temperature in K, P is the pressure in atm, and EDG is
the volumetric fraction of extra diluent gases. T0 and P0 are the reference temperatures and
pressures, 300 K and 1 atm respectively. Su0 = 36.5 cm/s, is the laminar burning speed of the
stoichiometric mixture at reference temperature and pressure of 300 K and 1 atm respectively. a1
211
and a2 are constants with values of -1.01 and -1.91 respectively. is a exponential constant
equal to 2.16. and are two exponents which represent the dependence of laminar burning
speed on temperature and pressure. It has been investigated that for most of hydrocarbons these
exponents vary by equivalence ratio [4, 5, and 7]. The proposed functions for the dependency of
and on equivalence ratio are:
21 ( 1.18.0 ) (7)
21
( 1.18.0 ) (8)
The constant values in equations (6) and (7) are: ( 36.01 , 2.22 ) and
( 21.01 , 22.02 ).The temperature range for equation (6) is 300<T <650 K. The range of
pressure for equation (6) is limited to smooth (non-cellular) flames. In all experiments, it was
observed that flame instability is very sensitive to pressure. This sensitivity varies by equivalence
ratio of the mixture. Fig. 7 shows cell formation pressure of all cases versus equivalence ratio.
This figure demonstrates that cell formation is strongly dependent on equivalence ratio.
Experimental observations have shown that for each equivalence ratio, there is a specific range
of pressure at which flame becomes cellular. The range of pressure for equation (6) is in non-
cellular region of Fig. 7.
Fig. 8 shows the comparison of and exponents with the results of other researchers.
Values of in this research are very close to the results of other researchers [4, 5, and 7]. Values
of are presented in Fig. 8 and this figure demonstrates that the results of this work is in the
middle of different researchers results.
9.5. Comparison with Other Measurements
The results of these experiments have been compared to those of others in the same
range. As it was noted before, the significance of this research is measuring the laminar burning
speeds at higher temperatures and pressures. In addition, the effect of EDG has been investigated
in a wide range of temperatures and pressures. Fig. 9 shows comparison with other researchers at
pressures of 1 and 2 atm. At 1 atm pressure, the agreement with other researchers is good in all
temperatures and equivalence ratios. It is seen that results of Egolfopoulos et al [6] are higher,
especially when mixture becomes richer. The theoretical results of Rohl and Peters [20] are
212
larger than experimental measurements in lean conditions. Also shown, are laminar burning
speeds at temperature of 600 K for the first time. At pressure of 2 atm, the agreement is good
with other researchers. It can be seen that the results of Bradley et al [4] are low because of their
lower pressure exponent values. The theoretical data of Rohl and Peters [20] is again higher than
experimental data in lean conditions.
Acknowledgments
This research has been done by support of Office of Naval Research (ONR) grant number
N00010-09-1-0479 under technical monitoring of Dr. Gabriel Roy.
Reference:
[1]. Iskender Gökalp and Etienne Lebas, Applied Thermal Engineering 24 (2004), Issues 11-
12, 1655-1663.
[2]. S. Consonni, E. D. Larson, J. Eng. Gas Turbines Power, 118(1996), Issue 3, 507.
[3]. John Brandenburg and Mohamed Elzooghby, “Ethanol Gel Based Fuel for Hybrid Rockets: The Golden Knight Hybrid Rocket Program at the University of Central Florida”, 43rd AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit 8 - 11 July 2007, Cincinnati, OH.
[4]. D. Bradley, M. Lawes, M.S. Mansour, Combust. Flame 156(2009), Issue 7, 1462-1470.
[5]. O.L Gülder, Nineteenth Symposium (International) on Combustion, The Combustion
Institute, (1982), pp. 275–281.
[6]. Egolfopoulos FN, D.X. Du, C.K. Law, Twenty-Fourth Symposium (International) on
Combustion, The Combustion Institute Pittsburgh, (1992), pp. 833–841.
[7]. S.Y. Liao, D.M. Jiang, Z.H. Huang, K. Zeng, Q. Cheng, Applied Thermal Engineering
27(2007), Issues 2-3, 374-380.
[8]. Hara Takashi and Tanoue Kimitoshi, the 31st FISITA World Automotive Congress
(FISITA 2006).
[9]. Shintre Parag, Vasudevan Raghavan, Combust. Flame 156 (2009) 997–1005.
[10]. Parsinejad F, Keck JC and Metghalchi H., Experiments in Fluids 43(2007), Number 6, 887-894.
[11]. Rahim F, Eisazadeh Far K, Parsinejad F, Andrews RJ, Metghalchi H. International Journal
213
of Thermodynamics 11(2008),151-161.
[12]. Metghalchi M, Keck JC, Combust. Flame 38(1980), 143-154.
[13]. Metghalchi M, Keck JC, Combust. Flame 48(1982), 191-21.
[14]. Eisazadeh Far K, Parsinejad F and Metghalchi H., Fuel 89 (2010) 1041–1049.
[15]. Parsinejad F, Arcari C, Metghalchi H. Combustion Science and Technology 178(2006),
178:975-1000(26).
[16]. Bradley, D., Hicks. R.A., Lawes. M, Sheppard. C.G., Woolley. R. Combust. Flame
115(1998), Issues 1-2, Pages 126-144.
[17]. Bradley D, Sheppart CGW, Woolley R, Greenhalgh DA, Lockett RD. Combust. Flame
122(2000), 195-209(15).
[18]. Sun, C. J., Sung, C. J., He, L. & Law, C. K., Combust. Flame 118(1999), 108–128.
[19]. Yuan. J., Ju. J., Law, C.K. (2007). Proceedings of the Combustion Institute, Vol. 31(2007),
pp. 1267-1274.
[20]. Olaf Rohl and Norbert Peters, Proceedings of the European Combustion Meeting 2009.
214
Time (ms)
Pre
ssu
re(a
tm)
0 50 100 1500
1
2
3
4
5
6
7 spherical vesselcylindrical vesselflame arrival to the wall in cylindrical vessel
Figure 1: comparison between the pressure of spherical and cylindrical vessels
215
=0.8 p/pi=1.02 p/pi=1.16 p/pi=1.93
=0.9 p/pi=1.04 p/pi=1.16 p/pi=2.08
=1 p/pi=1.04 p/pi=1.14 p/pi=2.25
=1.1 p/pi=1.05 p/pi=1.17 p/pi=2.28
Figure 2: Pictures of ethanol-air mixture, Pi = 2 atm, Ti = 450 K
216
Ln(P)
Ln
(T)
0 0.5 1 1.5 2 2.5 3 3.5 45
5.5
6
6.5
7 A: Pi=1 atm, Ti=300 KB: Pi=2.5 atm, Ti=377 KC: Pi=4 atm, Ti=423 KM
A
A'
B
B'
C
C'
M
TM=430K, PM=4.5 atm
Figure 3: Unburned gas conditions of ethanol-air mixtures
Stretch rate (1/s)
La
min
ar
bu
rnin
gsp
ee
d(m
/s)
30 40 50 60 70 80 900.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
=0.8, T=430K, P=4.5 atm
=1, T=400 K, P=3.3 atm
Figure 4: Laminar burning speed versus stretch rates
217
Temperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
300 350 400 450 50020
25
30
35
40
45
50
55
60
65
70 = 1 = 0.9 = 0.8Power law fit
Pi = 1 atm, Ti = 300 K
Temperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
350 400 450 500 550 60030
40
50
60
70
80
90
100 = 1.1 = 1 = 0.9 = 0.8Power law fit
Pi = 1 atm, Ti = 373 K
Temperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
460 480 500 520 540 560 580 600 620 64050
60
70
80
90
100
110
120
130 = 1.1 = 1 = 0.9 = 0.8Power law fit
Pi = 1 atm, Ti = 450 K
Figure 5: Laminar burning speeds of ethanol-air mixtures at different temperatures, pressures and equivalence ratios
218
Temperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
400 450 500 550 60040
45
50
55
60
65
70
75
80
85
90
95
100 EDG = 0%EDG = 5%EDG = 10%Power law fit
Pi = 1 atm, Ti = 373 K
Temperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
480 500 520 540 560 58050
55
60
65
70
75
80
85
90
95
100
105
110
115
120EDG = 0%EDG = 5%EDG = 10%Power law fit
Pi = 1 atm, Ti = 450 K
Figure 6: Dependence of laminar burning speeds of ethanol-air mixture on EDG gases
219
Cri
tica
lPre
ssu
re(a
tm)
0.8 0.9 1 1.12
3
4
5
6
7
8
9
Cellular
Non-cellular
Figure 7: Cell formation pressure versus equivalence ratio
220
0.7 0.8 0.9 1 1.1 1.21
1.2
1.4
1.6
1.8
2
2.2
2.4
Present studyBradley et al [4]Gulder [5]Liao et al [7]
0.7 0.8 0.9 1 1.1 1.2-0.5
-0.45
-0.4
-0.35
-0.3
-0.25
-0.2
-0.15
-0.1
Present studyBradley et al [4]Gulder [5]Liao et al [7]
Figure 8: values of and exponents versus
221
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
0.7 0.8 0.9 1 1.1 1.210
20
30
40
50
60
70
80
90
100
110
120
130
140
150
160
170
180 Present studyBradley et al [4]Egolfopoulos et al [6]Liao et al [7]Rohl and Peters [20]
453 K
363 K
298 K
P = 1 atm
600 K
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
0.7 0.8 0.9 1 1.1 1.210
20
30
40
50
60
70
80
90
100
110
120
130
140
150
160Present studyBradley et al [4]Gulder [5]Liao et al [7]Rohl and Peters [20]
300 K
453 K
P = 2 atm
600 K
Figure 9: laminar burning speeds of ethanol-air mixtures and comparison with other researchers
222
10. Laminar burning speeds of advanced bio-jet
fuels
223
10. Laminar burning speeds of advanced bio-jet
fuels
10.1. Bio-based Alternative Fuels for JP-8
Bio-jet fuels are important alternative energy resources for aviation purposes. These fuels
can be obtained from several resources like corn, sugar, algae, biomass, etc. due to water and
food resources limitation in the world it is preferred to use non-edible resources to produce bio-
jet fuels. One of the reliable resources for obtaining bio-jet fuels is biomass. Biomass is abundant
in nature and it does not waste edible resources. Biomass is a renewable resource of energy. The
produced CO2 from the combustion of biomass fuels can be a part of biomass creation cycle loop
in the nature. Therefore the net emitted CO2 of ethanol production and combustion is low and it
makes it a renewable and fairly clean fuel.
There are various classes of aviation biofuels. The most common ones are alcohol fuels.
They can be produced both from edible resources like corn and non-edible resources like
biomass. Among alcoholic fuels ethanol is the most popular one; it is widely used in land based
engines but not so popular in aviation engines. The ideal fuel for aviation fuel is the one which
can be used both as energy source and coolant. Currently, JP-8 fossil fuel is widely used in
aviation and satisfies the mentioned requirements. The attempt is focused on finding the best bio-
jet fuel which is similar to JP-8. The class that is most advanced is "hydrotreated renewable jet"
(HRJ), which is hydrotreated fats/oils.
This fuel is very similar to Fischer-Tropsch synthetic paraffinic kerosene. The fuel called
R-8 (POSF 5469) is a fuel produced by hydrotreating fats/oils (triglycerides) and contains n-
paraffins and iso-paraffins. HRJ fuels are predominantly n-paraffins and iso-paraffins. The other
fuel is produced from biomass by a different process, and contains aromatics. The applied bio-jet
feuels in this research will be ethanol, R-8 (POSF 5469), and POSF 5700. The laminar burning
speeds of these bio jet fuels will be measured and the results will be compared with those of JP-
8.
One of our major goals is to measure the laminar burning speeds of R-8 bio-jet fuel. Before
224
measuring the laminar burning speed it is essential to evaluate the thermo-physical properties of
this fuel. In this respect, we have used a Gas chromatography facility to analyze this fuel and
measure its heat capacity, enthalpy and entropy to develop polynomial functions in NASA
format. We have used a VARIAN CP-30 GC machine. Figure 1 shows the chromatograph of
this fuel. It can be seen that this fuel is composed of several elements and the major ones are n-
paraffins. After getting the components we have applied a statistical thermodynamic method to
calculate the thrmo-physical properties. The details of this model can be found in [18].
Figure 2 shows the ratio of heat capacity to gas constant versus temperature. It is shown that in
initial stages the heat capacities are different but by increasing the temperature they converge.
C15H32
C16H34
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C8H18
C7H16
R-8 bio-jet
C15H32
C16H34
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C8H18
C7H16
C15H32
C16H34
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C8H18C15H32
C16H34
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C15H32
C16H34
C15H32
C16H34
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C9H20
C10H22
C11H24
C12H26
C13H28
C14H30
C8H18
C7H16
R-8 bio-jet
Figure 1: Chromatograph of R-8
225
0
20
40
60
80
100
120
250 500 750 1000 1250 1500
T (K)
cp/R
R-8
JP-8
Figure 2: heat capacities of R-8 and JP-8 versus temperature
10.2. Laminar Burning Speeds
After calculating the thermodynamic properties of R-8 bio-jet fuel, laminar burning speeds of
this fuel was measured by the same method discussed before. Figure 3 shows the results of
laminar burning speeds of bio-jet fuels and ethanol. The results have been compared with the
data of conventional jet fuels (JP-8 and JP-10) and ethanol. It can be seen that among these fuels
JP-8 has the highest laminar burning speed. After that ethanol, JP-10 and R-8 has the lowest
laminar burning speed. However, more information and study is needed to measure the laminar
burning speeds of R-8.
226
Figure 3: Laminar burning speeds of JP-8, R-8, JP-10, and Ethanol fuels at several pressures and
temperatures, = 1
Temperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
580 600 620 640 660 680 70080
90
100
110
120
130
140
150
160
170
180
190
200 JP8R-8 (bio-jet)JP10Ethanol
T = 600 K
P = 2 atm
Temperature (K)
La
min
ar
bu
rnin
gsp
ee
d(c
m/s
)
580 600 620 640 660 680 70080
90
100
110
120
130
140
150
160
170
180
190
200 JP8R-8 (bio-jet)JP10Ethanol
T = 600 K
P = 1 atm
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11. Summary and Conclusions
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11. Summary and Conclusions
The summary of this thesis is described in following section. Each chapter (paper) has the
individual conclusions which will be described here.
11.1. Thermodynamic Properties of Ionized Gases at High Temperatures
Thermodynamic properties of air, argon, and helium have been calculated at high temperatures
using a novel cascade thermodynamic model. It was assumed that all species are in local
thermodynamic equilibrium. The model is based on statistical thermodynamics methods.
The calculated properties are: specific heat capacity, enthalpy of the mixture, mole fraction
of species, particle numbers, and density. It is shown that all these properties are very
temperature sensitive. It is also shown that number of ions and ionization level play an
important role in determining specific heat capacities and particle numbers in the mixture.
Results are compared with those of other researchers and good agreement is obtained in regions
where the results overlap.
11.2. A Thermodynamic Model for Argon Plasma Kernel Formation
Formation of argon plasma kernel has been studied experimentally and theoretically. The
experiments were performed at constant pressure in a shadowgraph system. They have been
performed with two different discharged energies to investigate the effect of spark energy. Radii
of argon plasma kernel were measured optically. A thermodynamic model was developed to
predict the measured radii under initial conditions of experiments. The major conclusions are:
1- It can be assumed that the plasma kernel expands in a constant pressure and constant
mass condition.
2- Total number of moles increases as the temperature of the gas increases and it is the main
source of kernel expansion at constant pressure and constant mass condition.
3- Increase of heat capacity of the plasma gases at high temperatures has a very important
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role in temperature and growth mechanism of the kernel.
4- Initial volume and initial temperature of the kernel have a great effect on temperature of
the kernel. However, they do not have a majo effect on the size of the kernel.
5- Cathode-anode falls are the major source of energy losses. Radiation is another source of
energy losses which becomes more important at higher discharge energies due to higher kernel
temperature. A small portion of discharged energy is converted to the thermal energy depending
on discharged energy amount. This portion is less than 10%.
This model can be extended to combustible mixtures as well to investigate the spark ignition
and flame formation mechanism of engines and other combustors to improve combustion
process.
11.3. On Flame Kernel Formation and Propagation in Premixed Gases
An experimental and theoretical study was done on flame kernel formation and propagation of
premixed gases. The formation of hot plasma during the spark discharge was studied
experimentally and a thermodynamic model was developed for air plasma. The effect of various
parameters on plasma kernel formation and propagation were studied. The major conclusions are
as follows:
1- A major part of discharge energy is dissipated by cathode fall energy losses. The amount of
dissipated cathode fall energies depends on the amount and duration of discharge energy.
Radiation is the important source of energy losses in plasma. The amount of radiation energy
loss strongly depends on the temperature of the hot plasma. However, when self-sustained flame
establishes radiation is not an important source of energy loss. Only about 10-25% of the,
electrical energy is converted to thermal energy.
2- It was concluded that the plasma expands in a constant mass and pressure process with
increasing number of moles due to ionization.
3- Increase in heat capacity at high temperatures is an important factor in dynamics and
temperature rise in the kernel.
4- Initial temperature and initial volume of the kernel are important parameters in growth and
temperature of the plasma kernel.
5- The amount of electrical energy input is important to the size and temperature of the kernel.
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In second part of this study, the propagation of premixed methane/air flames was studied
experimentally and theoretically. The experiments were performed on methane/air flames at
atmospheric pressure and temperature, with two different spark electrodes, and two different
spark energies. The conclusions are as follows:
6- The amount of input electrical energy is important in the location of flame but it does not
affect the asymptotic flame speed.
7- The geometry of the spark electrode does not affect the flame speed and location of
flame.
8- The laminar burning speed was measured by this model and it was in good agreement
with experimental results of other researchers.
9- Laminar flame needs a certain amount of time to become self-sustained. This time scale
depends on the composition of the mixture and input electrical energy. This time scale increases
when the mixture becomes richer.
11.4. A Thermodynamic Model to Calculate Burning Speed of Methane-Air- Diluent
Mixtures
Burning speeds for methane-air-diluent flames over a wide range of pressures, temperatures,
stoichiometries, and diluent fractions have been determined from pressure measurements made
in a spherical combustion chamber. The burning speed were calculated from the pressure records
using a thermodynamic model which includes the effects of radiation and conduction heat losses
to the wall and electrodes and the temperature rise in the preheat zone. Shadowgraphs were taken
through end windows in a cylindrical chamber of the same volume as the spherical chamber to
determine the shape and structure of the flames for which burning speeds were measured. Both
spherical and distorted flames having smooth, cracked and cellular fronts were observed. For
very slow flames, buoyant rise was also observed. For comparison with the measurements, flame
speeds were calculated using the PREMIX code with GRI-Mech 3.0 kinetics. The following
conclusions were drawn:
1. The measured burning speeds of stoichiometric methane-air-diluent mixtures at initial
pressures and temperatures of 1.0 atm and 298 K and 0-15% diluent are in reasonable agreement
with values calculated from the PREMIX code using GRI-Mech 3.0 kinetics. Under these
conditions all the flames observed were smooth and spherical.
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2. For initial pressures and temperatures of 5.0 atm and 298 K and 0-15% diluent, stoichiometric
and lean methane-air-diluent flames were cracked at low pressures and high diluent fractions and
cellular at high pressures and low diluent fractions. The measured burning speeds for cracked
flames agree reasonably well with PREMIX values but are higher than PREMIX values for
cellular flames suggesting that cellularity may increase the burning speed.
3. For rich methane-air-diluent mixtures at initial pressures and temperatures of 5.0 atm and 298
K, and 0-10% diluent, all the flames observed were smooth but the measured burning speeds
were significantly lower than PREMIX calculations. The most probable reason for this is the
omission of reactions involving alkyl peroxides form the GRI-Mech 3.0 kinetics.
4. Further work is needed to determine more precisely the conditions under which cracking and
cellularity occur and whether the observed discrepancies between the measured burning speeds
and PREMIX calculations are due to cellularity or a failure of the GRI-Mech 3.0 kinetics.
11.5. Flame Structure and Laminar Burning Speeds of JP-8/air Premixed Mixtures at
High Temperatures and Pressures
1. The shape and structure of JP-8/air flames were studied at various temperatures, pressures and
equivalence ratios. The effects of equivalence ratio and pressure on the structure of the flame
were striking. Initial pressure did not play any significant role in the turbulization of the flames
and there was a specific range of pressure for the cell formation of any flame in a particular
equivalence ratio.
2. Laminar burning speeds were calculated for JP-8/air mixtures. The calculations were done in
temperature and pressure ranges in which flames were laminar. It was observed that laminar
burning speed increases as temperature increases and decreases as pressure increases.
3. Burned mass fraction rate of cellular flames were measured for various temperatures and
pressures. It is concluded that the slope of burned mass fraction rate versus temperature increases
as temperature and pressure increase. This is due to the increase of flame surface in a cellular
flame.
4. A power law correlation was developed for the laminar speed of JP-8/air mixtures by
nonlinear least square fit method. This fitted equation is valid in laminar flame cases.
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11.6. The Effect of Diluent on Flame Structure and Laminar Burning Speeds of JP-
8/oxidizer/diluent Premixed Flames
The effect of diluents on flame structure and laminar burning speeds has been studied.
The addition of EDG did not have a remarkable effect on the stability of JP-8/air/EDG flames
compared with JP-8/air flames, but it decreased the laminar burning speeds due to decreasing the
adiabatic flame temperature. It was observed that for a heavy hydrocarbon premixed flame such
as for JP-8, increasing pressure causes flame instability. For lean JP-8/air and JP-8/air/EDG
flames hydrodynamic instabilities are observed. Increasing pressure decreases the flame
thickness and reduces the resistance of flame against perturbations associated with expansion
ratio. This leads to hydrodynamic instabilities. The other factor which causes flame instability is
enriching the mixture in JP-8/air and JP-8/air/EDG mixtures. This is due reducing reduction of
the Le number of the flame associated with deficient reactant. Pe numbers of unstable flames
were calculated and it was observed that the critical Pe number is strongly dependent on the
equivalence ratio and it decreases by increasing the equivalence ratio. Clearly, it can be
concluded that rich mixtures are more vulnerable to perturbations.
A set of experiments were performed with helium and argon as diluents. It was observed that
argon causes more instabilities than air. This is because of the lower heat diffusivity of argon
compared to air and helium. JP-8/oxygen/helium mixtures have the most stable flames. This is
due to their high thermal diffusivities. It was observed in experiments that the JP-
8/oxygen/helium flames are stable at higher temperatures and pressures in which JP-8/air and JP-
8/oxygen/argon flame were unstable. The laminar burning speeds of JP-8/oxygen/helium flames
were measured and it was indicated that helium increases the laminar burning speeds
dramatically because of higher adiabatic flame temperatures.
11.7. Laminar Burning Speeds of Ethanol/Air/Diluent Mixtures
Laminar burning speeds of ethanol-air mixtures were measured at high temperatures,
pressures, various equivalence ratios and with extra diluent gases to represent residual gases in
engines. It was concluded that in rich ethanol-air mixtures, instability occurs at lower pressures
and temperatures. It was also resulted that pressure intensifies the onset of instability in ethanol-
air flames. Measured and fitted results showed that the exponents of normalized pressure and
temperature vary with equivalence ratio. Laminar burning speeds were measured in temperature
range of 300<T<650 K and pressure range of 1<P<5 atm. Extra diluent gases have an important
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effect on laminar burning speed values. Addition of these gases to the mixture decreases the
laminar burning speed significantly due to flame temperature reduction. The measured laminar
burning speeds were fitted to a power law function and the results were in good agreement with
other researchers’.